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itsgerges · 5 months ago

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The Solar Planet Nature Definition (Revised)

NOTICE

The revised paper is typical the original one with one addition (The Modified Proof For Planet Nature Definition Pages No. 304-330)

Planet Nature Definition Without Proof Is Written In Pages No. (1-6)

My Research Presentation Is Written In Pages No. (7-303)

Planet Creation And Nature

In this analysis I prove- Planet is created based on a coherence of light- here- I define planet creation as example for the matter creation generally- and- I prove planet is created by a coherence of light- means- the matter is created by a coherence of light.

I want to say -

The main idea tells- Planet is created based on two energies interaction (or two light beams coherence)– one source of energy can NOT create any matter (Nor Any Planet)

Planet Nature Analysis

Let's Discuss Planet Nature Features in following

(1ST FEATURE)

Planet Is An Intersection Point Between Two Energies- Imagine we have one energy moves in (x-axis direction) and have also another energy moves in (y-axis direction)- the two energies meet each other in One Point which is (an intersection point) – this point is A Planet

This is similar to two ropes or cables or strings are connected together by one knot (or joint)- the knot is connected with both ropes and each rope motion effect on this knot motion direction-

This explanation is typical to The Puppets Theater-the puppets are connected with strings and these strings define these puppets motions direction-shortly- Planet motion depends on the motions of the energies by which this planet is created-simply Planet is an intersection point between two energies and these energies motions effect on this planet motion Direction

Notice- The data doesn't show any effect of planet mass on its motion.

Shortly– Theprevious explanation tells Planet is created based on two energies- one energy is NOT enough to create a planet (the matter)

(2ND FEATURE)

The Matter Is Created In Pairs And No Single Matter Can Be Created -AND

Planet Creation And Motion Are Defined By Another Planet Motion

As in the experiment- (Gamma ray 1.2 Mev can produce electron and positron)- that proves the matter is created in pairs and no single matter can be created- also the creation system (male and female) supports this same fact- I want to say- all matters are created similar to the electron and positron from Gamma ray- simply- the matter is created in pairs- for that- Planets also are created in pairs and no single planet can be created- Planet velocity and diameters analysis prove this fact clearly- the proves discussion are found in page no. (303)

This feature also proves the matter is created based on two energies- also in the Gamma ray experiment because we need two energies– the first energy is Gamma ray 1.2 Mev from which electron and positron can be produced– the second energy is the used energy to produce electron and positron from Gamma ray- means-the method by which Gamma ray 1.2 Mev can produce electron and positron- please note the principle idea tells (the matter is created in pairs and no single matter can be created-AND- the matter creation needs two energies because one energy is not enough to create the matter)

Please note- Feature no.(1) tells, planet is an intersection point (a knot) between two energies- but Feature no. (2) tells matter is created in pairs and no single matter can be created– that means- these intersection points (knots) are created in pairs and can't be created individually-BUT Why?? because the matter creation depends on the energy reflection- the reflection causes to create the matter is pairs- this fact is explained in feature No. (5)

(3RD FEATURE)

Planet Diameter Is Created As A Function In Its Rotation Period

This fact is proved by my planet diameter equation

Please note-my planet diameter equation proves Planet diameter is created based on two motions because the equation uses two planets velocities (v1/v2) that proves two motions are required to produce planet diameter which supports our principle tells (Planet matter is created depending on two energies because one energy is not enough to produce the matter)

(4TH FEATURE)

I have two examples can explain the matter nature

(1st Example) the matter is similar to creature muscles- shortly- even if the muscle is very strong as a rock- we understand this muscle is found depending on the blood motion-and any change in the blood motion can effect on the muscle dimensions and ability- similar to that the matter is created depending on the motion of the energies Based on which this matter is created-

(2nd Example)–If the space is similar to the sea of water- the matter is similar to a whirlpool (vortex) found on the sea page- we understand the whirlpool (vortex) is created by the sea water but it has a distinguish picture from the sea waves and it moves by a different velocity from the sea waves- that explains how the moving energy can effect on the matter creation data- for example- we have a whirlpool (vortex) its diameter is 2 meters- why does this diameter equal= 2 meters? The diameter is created depending on the water velocity, pressure, amount and motion angle and many other features of (the moving water)- the moving water creates this whirlpool with diameter 2 meters and as long as the water motion is not changed this diameter will not be changed also-

Notice we understand the whirlpool (vortex) is found because at least two streams of water meet each other- means- one stream is not enough to create a whirlpool (vortex)– similar to that- one energy is not enough to cause the matter creation but two energies are required to cause the matter creation- because the matter is an intersection point between these two energies-

(5TH FEATURE)

Why should The Matter be Created In Pairs And No Single Matter Can Be Created?

Let's try to answer

The matter creation needs two energies because the matter is an intersection point between these two energies- means- the matter creation (and planet creation) needs two energies-

In the solar system one of these two energies is a reflected energy- let's explain that

The planets orbits are created before any planet creation-and – all planets orbits are created from the same one energy and each planet orbit has a part of this one energy and this part of energy is the orbit creation reason (because Space is energy)- means- each planet orbit is created depending on a part of this one energy

But

There's another energy is reflected and passed through all planets orbits – let's give example to explain that

Imagine we have 9 neighbor whirlpools (vortex) on the sea page- suppose one strong wave of water passes through these 9 whirlpools- imagine the water of this strong wave is colored by blue color- because the strong wave passes through the 9 whirlpools we will see that all whirlpools have this blue color in their waters because this strong water wave passes through the 9 whirlpools and creates effects on all of them-

Similar to that- one energy is reflected and passed through all solar planets orbits (before any planet creation)- by this energy each orbit becomes have two energies- which are (1st energy) the orbit energy by which the orbit is created (2nd energy) the reflected energy which is passed through all orbits- by that- each orbit has two energies- now this energy is a reflected energy and the reflection caused the matter to be created in pairs- why??

The energy reflection causes to create complementary values- imagine a light beam is reflected on some mirror- here–we have the original light beam and the reflected light beam- the two light beams are similar in all data but in opposite directions- that tells the energy reflection causes to create the data reflected on each other (and complementary one another)- and the complementary data cause to create the matters in pairs and no single matter can be created-

Shortly -because the energy is reflected in the solar system the matter is created in pairs by the energy reflection effect where No single matter can be created

(6TH FEATURE)

How can planet matter be created by two energies? By what method this creation can be done? There are three methods can be used

(First Method) Can Planet Be Created As A Wave?

We know the particle has double nature and behaves as a wave-

Let's suppose planet is created as a wave? How can the wave be created?

We need two motions perpendicular on each other- means- we need two energies perpendicular on each other- means- by two energies motions a wave can be created and this wave will be a planet - Just we need to suppose that the two energies in each orbit are perpendicular on each other and that will cause to create the planet as a wave

(Second Method) The Energy Reflection

As explained the energy reflection causes to create the values in pairs (reflected on each other and complementary one another) because the original values produce reflected values and that cause the values to be created in pairs-and that cause the matter to be created in pairs- shortly- the energy reflection is the reason to create the matter in pairs- that causes planets data to be created in pairs complementary one another- (as proved by planet velocity definition by the rule v1v2=constant= 322)

Also planet diameter follows this same rule (R1R2=Constant)- because the planets are created in pairs and the matter generally is created in pairs (as electron and positron from Gamma ray 1.2 Mev)

Shortly- The Creation In Pairs Is Done Basically Because Of The Energy Reflection

(Third Method) The Coherence Of Light

Young coherence of light produces the interference (bright fringes and dark fringes)- let's suppose– we see the bright fringes as planets- and if fringe breadth is comparable with planet diameter- we will find that- the solar planets distribution is typical to the interference of Young- because- the greatest diameter planet "Jupiter" is found in the middle and the other planets diameters are decreased gradually on both sides typical to the fringes distribution in Young interference- please note- I have proved Mars original orbit was between Mercury and Venus and Mars had Migrated to its current orbit by that the inner planets original order was (Mercury-Mars- Venus- The Earth) the diameters are decreased gradually from the Earth to Mercury typical to Young Interference-

Notice

We understand, the matter is created in pairs because of the energy reflection and if the planets are created by the coherence of light that tells the coherence of light must contain reflection of energy and this is a fact- means- the coherence of light contains reflection of energy and this reflection is seen in the fringes distribution because the fringes breath is decreased gradually on both sides means each side is reflected on the other and that shows there's a reflection of energy found in the coherence of light-

NOTICE

The Proves Discussion for The Planet Nature Definition is found in pages (303-319)

My Research Presentation

I- Research Methodology

II- Major Problems In The Physics Book

(1) The Physicist Wrong Vision Contradicts The Nature System

(2) Planet Motion Energy Definition

(3) Mass Gravity Force Analysis

(4) The Matter Creation And Its Nature Definition

III- My 5 Equations

(1st equation) Planet orbital distance equation- the equation proves planet orbital distance is defined based on its neighbor orbital distance and no planet mass is used for this definition- Newton is wrong-

(4th equation) Planet diameter equation- the equation proves planet diameter is created based on a geometrical rule (NO Random Creation- the big bang theory is wrong) -also the equation proves the matter is created in pairs (as electron and positron are produced by Gamma ray 1.2 Mev)

(5th equation) Planet velocity equation- the equation proves planet mass has no effect on this planet velocity definition

IV- The Research Discovery

The Gravitational Waves Are Produced By The Planets Motions Energies And Not By The Gravitational Field- Moreover- There's No Gravitational Field

V- The Gravitational Waves Reflection Analysis

The Gravitational Waves Reflection Proves The Waves Are Produced By The Planets Motions Energies

VI- The Research Hypothesis

The Sun Is Not Doing Nuclear Fusion To Produce Its Rays- Instead- The Sun Rays Are Produced By The Gravitational Waves Motions Energies- And The Gravitational Waves Are Produced By The Planets Motions Energies- Means- The Sun Rays Is Created By The Planets Motions Energies Total- Shortly- The Sun Is A Phenomenon Created After All Planets Creation And Motion Because The Sun Is Created By The Planets Motions Energies.

That explains why the sun corona temperature is 5 million Kelvin but the sun surface temperature is 5800 Kelvin- because the energy is not produced from the sun body but the energy comes from out of the sun body for that the energy out of the sun is so greater than the energy inside the sun (the energy comes from the gravitational waves which are produced by the planets motions energies total)

The Hypothesis Explanation

The Sun Rays Creation Process

This Is Extraordinary: Gravity Can Create Light, All on Its Own

https://www.msn.com/en-us/news/technology/this-is-extraordinary-gravity-can-create-light-all-on-its-own/ar-AA19YL5d?ocid=hpmsnHYPERLINK "https://www.msn.com/en-us/news/technology/this-is-extraordinary-gravity-can-create-light-all-on-its-own/ar-AA19YL5d?ocid=hpmsn&cvid=620db4352aa943e2b454919a7b724604&ei=83"&HYPERLINK "https://www.msn.com/en-us/news/technology/this-is-extraordinary-gravity-can-create-light-all-on-its-own/ar-AA19YL5d?ocid=hpmsn&cvid=620db4352aa943e2b454919a7b724604&ei=83"cvid=620db4352aa943e2b454919a7b724604HYPERLINK "https://www.msn.com/en-us/news/technology/this-is-extraordinary-gravity-can-create-light-all-on-its-own/ar-AA19YL5d?ocid=hpmsn&cvid=620db4352aa943e2b454919a7b724604&ei=83"&HYPERLINK "https://www.msn.com/en-us/news/technology/this-is-extraordinary-gravity-can-create-light-all-on-its-own/ar-AA19YL5d?ocid=hpmsn&cvid=620db4352aa943e2b454919a7b724604&ei=83"ei=83

This new article tells the gravitational waves can move by speed of light and can produce a light beam- I claim The Sun Rays are produced based on this method by the gravitational waves motions and not by the sun nuclear fusion process- also –No star rays is produced by the nuclear fusion process but all rays are created by the gravitational waves motions energies as the article states.

Here we have four questions to answer

How can the gravitational waves be produced by the planets motions energies?

How can the gravitational waves move by speed of light?

How can the gravitational waves motions produce a light beam?

Can The Planets Motions Energies Total Be Sufficient To Produce The Sun Rays?

Let's answer in following

1st Question

How Can The Gravitational Waves Be Produced By Planets Motions Energies?

Planet motion produces energy (1/2 mv^2) but where's this motion energy? Planet can NOT store its motion energy inside its body because It would raise its temperature- and no planet temperature is raised by its motion- logically- planet motion energy is stored in the space in moving waves –Means- planet motion in space is similar to a fish swimming in the sea- the fish swimming creates waves in the sea and similar to that - planet motion energy creates waves in the space- and - fish swims because it hits the water by its body and that creates waves in the water- and these waves move by a velocity equal the fish velocity because of the reaction force- similar to that- Planet moves in the space and its motion energy creates waves in the space and these waves move by velocity equal this planet velocity- for example- Mercury (47.4 km/s) moves and its motion energy creates waves in the space and these waves move by equal velocity (47.4 km/s)

Shortly- the planets move and their motions create waves in the space and each wave moves by velocity equal its planet velocity

AND the planets revolve around the sun in the same one direction and for that their motions energies create waves in the space and these waves move perpendicular on the revolution direction (Toward Pluto orbit)

AND in Pluto orbit these waves are unified together into one unified wave- this wave moves by a velocity= 205.8 km/s where The 9 planets velocities total=176 km/s but I add the Earth moon velocity (29.8 km/s) that makes the total to be 205.8 km/s – I add the moon velocity because the energy is stored finally in the moon orbit-

Note- The moon and the Earth revolve around the sun together for that the moon velocity is considered equal the Earth velocity relative to (the sun) –

NOW the unified wave moves by (205.8 km/s) is the gravitational wave-

The scientists discovered these waves in the space and they called them (gravitational waves) supposing these waves are produced by the sun gravitational field- BUT Planet motion energy must be stored in the space as moving waves – as proved by the previous analysis -means- even if There's NO Gravitational field at all there's a strong reason to find waves in the space because these waves are created by the planets motions energies

Note- I refute the sun gravitational field theory- and prove the sun has no massive gravity and also NO planet moves by the sun gravity

The Conclusion

The Unified Wave Its Velocity 205.8 Km/S Is The Gravitational Wave

Notice - the new article still believes that the gravitational waves are produced by the gravitational field- I refuse this idea and prove the waves are produced by the planets motions energies but I need the article because it tells the waves can move by speed of light and can produce the light beam where I suppose the sun rays is created by this method

The Answer Of The Questions No. (2) And No. (3)

2ndQuestion How Can The Gravitational Waves Move By Speed Of Light? AND

3rdQuestion How Can The Gravitational Waves Motions Produce A Light Beam?

What Do We Have?

We have One unified wave moves by velocity 205.8 km/s

What Do We Need?

We need to accelerate the unified wave to move by speed of light (C=300000 km/s) and this wave should produce (A Light Beam)

We know the light beam is produced from (C^2= Squared Speed Of Light)

Technically- How To Solve This Problem?

We Need To Square The Wave Velocity

Let's see my hypothesis (The Gravitational Waves Reflection Causes To Square The Wave Velocity) - let's see if this hypothesis can solve the problem

(a)

(205.8)^2 x 7.1 = 300000 km/s = C = (speed of light)

Where

205.8 km/s= the velocity of the unified wave (the gravitational wave)

7.1 is Lorentz length contraction effect rate for speed (0.99 C)

Let's discuss the equation

The unified wave moves by (205.8 km/s) – and this wave is reflected- the wave reflection causes to square its velocity – for that the velocity (205.8 km/s) is squared and be (205.8 km/s)^2= 42354 km/s

But Lorentz length contraction effect rate causes to increase the distance 42354 km to be (42354 x 7.1 = 300000 km) – means- the speed 42354 km/s is accelerated to be 300000 km/s = C=speed of light by Lorentz length contraction effect – we understand the rate 7.1 causes to contract the distances but here the rate increases the distances because the wave reflection causes to reflect the geometrical effects.

Conclusion No. (1)

The Wave Reflection Causes To accelerate the unified wave from (205.8 km/s) to move by speed of light (C=300000 km/s)

(b)

Now we have a gravitational wave moves by speed of light (C=300000 km/s)

This wave is reflected one more time

The gravitational wave reflection causes to square its speed by that – the wave speed was = speed of light (C=300000 km/s) before the reflection and after the reflection this speed will be (C^2=Squared Speed Of Light)

The light beam is produced from this value (C^2=Squared Speed Of Light)

Now we know how the unified wave (205.8 km/s) can be accelerated to move by speed of light (C=300000 km/s) and how this wave can produce a light beam

Conclusion No. (2)

The Gravitational Wave Reflection Causes To Square The Wave Velocity

This is the main useful result from the wave reflection- because without the squaring of the wave velocity no acceleration can be done for the wave and by that the gravitational wave can't move by speed of light Nor produce any light beam

Notice (1)

The waves are reflected three times in the solar system and the abstract provides strong proves for these reflections and more proves are found in the paper- the waves reflection causes basic changes in planets data and I suppose – the waves reflection causes also to square the waves velocity

Notice (2)

The rate 7.1 is produced by Lorentz length contraction effect as a result for motion by speed (.99C= 297000 km/s)- I proved this fact in (Item no. 5-6 Can Relativistic Effects Be Found In The Solar System?)

THE SUN POINT CREATION

The sun point of space has geometrical features enable to produce the sun rays and that means – the sun rays can be created only in the sun corona and far from the sun NO light beam can be created – let's see the sun geometrical features in following

(i)

The Sun Point Is A Stationary Point Its Velocity 1 km/s = Zero Approximately

This is important feature – Because

All motions are done relative to the sun point of space – for example- Pluto velocity is 4.7 km/s –means- Pluto moves by 4.7 km/s relative to the sun point of space – Shortly- the whole solar system is in motion (space and planets are in motion) but the sun point is stationary (static point moves by velocity 1 km/s = Zero approximately) Means- the solar system is similar to a sea of water and the sun is similar to a vortex or whirlpool found on the sea page – the vortex doesn’t move with the sea waves -Shortly- the sun point of space is the stationary point in the solar system and all motions are done relative to the sun point of space-

Example – Venus moves by 35 km/s that means Venus moves by 35 km/s relative to the sun point of space – also we know Venus motion produces energy and this energy creates waves in the space and these waves move by velocity 35 km/s – means- these waves move by 35 km/s relative to the sun point of space-

(ii)

Why Is It Necessary For The Sun Point To Be Stationary Point? Because

1- The Gravitational Wave (Unified Wave) Moves By Speed Of Light Relative To The Sun

2- The Gravitational Wave Can NOT Move By Speed Greater Than Speed Of light

3- The Wave Reflection Causes To Square The Different Speed Between The Gravitational Wave Speed And The Sun Point Motion Speed

4- If The Different Speed Is Less Than Speed Of Light (C=300000 Km/S) The Speed Squaring Process Will Never Produce The Value (C^2= Squared Speed Of Light) – means- No Light Beam Can Be Created

Now we see the necessity to make the sun point as stationary point moves by (Zero approximately =1 km/s) – because – if the sun point moves by any higher speed than (1 km/s) the different speed will be less than speed of light and the squared value will be less than (C^2) and No light beam can be created

Now let's ask- while the space is in motion as the sea of water – how can this stationary point be created? let's answer in following

(iii)

The planets were created before the sun creation and the planets revolve around a point in space (any point in space) the revolution creates two velocities on both sides of the revolution- the two velocities are equal in value opposite in direction- the total be Zero- means- the revolution motion creates a stationary point in the revolution center-

By That -the sun point of space is created as a stationary point- and the sun point is the only stationary point in the solar system- for that all motions are done relative to the sun point of space-

4th Question

Can The Planets Motions Energies Total Be Sufficient To Produce The Sun Rays? the question is logical because

Planet motion energy (1/2 mv^2) is so small energy and the sun rays energy is massive energy -for that- It's Logical Question To Know How Can The Planets Motions Energies Total Be Sufficient To Produce The Sun Rays?

Let's answer in following

(1)

The secret is the rates of time using-

The planets motions use different rates of time- by that- the planets motions energies can be accumulated during long period of time to produce massive energy sufficient to produce the sun rays – let's give examples

Example No. (1)

(One Solar Day Of The Sun Clock = 365.25 Solar Days Of The Earth Clock)

By this rate of time– The Earth motion energy for one complete year can be used by the sun in one solar day – in fact- the solar planets motions energies total during one complete year (365.25 solar days) is accumulated and stored in one energy and be used by the sun motion on one solar day that causes to accumulate massive energy to be used (notice 1461 days = 365+365+365+366)

Example No. (2)

(One Second Of The Sun Clock=1461Seconds Of The Gravitational Wave Clock)

We remember the unified wave (the gravitational wave) moves by 205.8 km/s -And – the gravitational wave moves in 1461 seconds a distance = 300000 km -BUT the Sun clock doesn't see this period 1461 seconds but sees only the period (ONE SECOND) – means-

The distance 300000 km is passed in (ONE SECOND)only for the sun clock– That causes the gravitational wave to move by speed of light (C=300000 km/s) relative to The Sun – (the rate of time using and effect is explained in details in item no VII)

VII- The Solar System Description Refutation

(The Sun Is The Planets Motions Result But The Description Supposes The Sun Is The Planets Motions Reason) and (The Matter Is Created Depending On Its Motion But The Description Supposes The Matter Is Created Independently From Any Motion)

VIII – The Planets Motions Use Different Rates Of Time

IX - The Physicist Wrong Vision Proves

X - The Refutations Of Many Theories In The Physics Book

XI - The Proves For My Theory

(There's A Light Beam Moves By Speed 1.16 Million Km Per Second)

XII-The Solar System History And Neptune Orbit Creation

First Item - Research Methodology

I use the planets data analysis to discover the planets creation and motion facts–

In details- I try to discover how the planet get its data- for example – why Jupiter diameter is 142984 km? why Neptune axel tilt is 28.3 deg? why Pluto orbital period is 90560 days? This method helps greatly to discover the solar system facts let's provide two examples to explain how this method works

Example No. (1)

Why Is The Moon Orbital Apogee Radius = 406000 Km?

The moon daily displacement =88000 km and during 29.53 days (the moon day period) the displacements total be = 2.598 million km = 2π x 413600 km

The data tells us the moon orbital apogee radius should be 413600 km and also it tells, because the moon daily displacement (88000 km) is so long, the moon should revolve around the Earth through this apogee orbit its radius (413600 km) only and can't revolve around the Earth through any more near orbit…

Not Facts

The moon orbital apogee radius =406000 km only and the moon revolves around the Earth through near orbits and can reach to perigee radius (363000 km).

How Can The Moon Do That?

The intelligent moon creates an angle (θ) between its motion direction and its orbit horizontal level by that the real displacement (L) through the orbit be less than (88000 km) because it be (L = 88000 km cos θ), as a result the total displacements be less than (2.598 million km) and that makes the moon orbital apogee radius to be decreased from 413600 km to 406000 km.

We should pay attention for the angle (θ), because this angle controls the moon motion features – where- with the angle (θ) increasing the real displacement (L) be shorter and the moon can revolve around the Earth through more near orbits – but –with the angle (θ) deceasing the real displacement (L) be longer and that pushes the moon far from the Earth to more far orbits- The moon orbital motion equation depends on this angle (θ) it tells θ1 = θ0 +1.7 deg where (θ1) = today angle and (θ0) =yesterday angle and 1.7 deg is used as the moon motion degrees per solar day for the equation

Example No. (2)

Can Mars Itself Cause The Earth Moon Creation?

Giant-impact hypothesis tells (NO) – but let's see the planets data analysis

I Suppose - Mars Original Orbit Was Between Mercury And Venus

The order (Mercury – Mars – Venus – Earth) shows correct order in planets diameters (and masses), and orbital distances - BUT – Mars had migrated from its original orbit (between Mercury and Venus) to its current one (227.9 million km) and Mars had collided with Venus and then with the Earth in its migration motion – and Mars itself has caused the Earth moon creation- My Mars Migration Theory answers many left questions by Giant-Impact Hypothesis – for example -

Why Does Venus Have No Moon? Mars had migrated from its original orbit (between Mercury and Venus) – and moved to its current orbit (227.9 million km) – BUT- Mars had moved by a force – and then Mars had collided with Venus –and Mars had pushed ALL DEBRIS with it in its Motion Direction because of its strong motion - Venus had found no debris around and for that Venus couldn't create its moon –But – The Earth mass is greater than Venus' and the debris lost some of their momentum for that the Earth could attracted some debris and created its moon-Mars has 2 moons and this fact supports my theory because Mars with small mass could attract two moons because the debris were around it while Venus has greater mass but couldn't create its own moon because the debris are moved with Mars motion- the rest debris are attracted by Jupiter gravity and created the asteroid belt

Shortly

The planet data analysis compares between the theory and the planets data to see if there's harmony between them and if the data logical analysis supports the theory

Second Item - Major Problems In The Physics Book

(1) The Physicist Wrong Vision Contradicts The Nature System

(2) Planet Motion Energy Definition

(3) Mass Gravity Force Analysis

(4) The Matter Creation And Its Nature Definition

1stProblem The Physicist wrong Vision Contradicts The Nature System

The Physicist Vision

The physicist supposes there's (a unit of building)- by that- the physicist sees the matter (mass) as a wall and this wall is consisted of bricks (small similar units) and the physicist searches for this (unit of building)–

For that the physicist divided the matter and found the particles and then the particle is divided into Molecules and the Molecule is divided into atoms and the atom is divided into nucleus and electron moves around and the nucleus is divided into proton and Neutron- and the proton is divided into quarks …etc

The physicist searches for the building unit- for that he divides anything to reach to this building unit-

The Nature System Vision

The Nature designer aims to create INTEGRATION- as the marriage– male and female- For that- the matter is created complementary one another-means- The Matter Is Created In Pairs (as Gamma ray 1.2 Mev produces electron and positron)

No building unit- AND

I want to show how the physicist causes fatal error for the research method while the physicist divides the elements (from matter to particle to molecule to atom to proton to quarks …etc) this division from out into inner till reach to very small unit which the physicist considered the building unit – that causes to destroy the geometrical design of the integration process- Shortly- the physicist sees a universe (never be created by the designer)- while the designer created the integration is a goal and created tools to perform this integration the physicist destroyed the integration tools while he searched for the building unit which is not found at all.

NOTICE

Another point shows the physicist wrong vision is (The Planet Motion)

While the solar planets move as gears in one machine and all planets motions are unified into one unified general motion- means- all planets motions are unified and produce one result only (one unified motion)- the physicist supposes each planet motion is independent-by that- in place of one machine of gears moves and produces one unified motion (one result) the physicist told us each planet motion is independent and No unification is found for the planets motions –here – one more time the physicist sees very different picture from the real one- in place of one hand has five fingers the physicist sees five independent moving fingers

2ndProblem Planet Motion Energy Definition

Let's remember this question where's Planet Motion Energy?

We agreed planet motion produces energy (1/2 mv^2) and this energy must be stored in the space as moving waves because planet can NOT store its motion energy inside its body otherwise this planet temperature would be raised- that tells- the space has moving waves produced by planet motion energy

Also –we agreed- planet motion energy creates waves in the space and these waves move by velocity equal this planet velocity-

Shortly- for example- Mercury (47.4 km/s) moves in the space and its motion energy produces waves in the space and these waves move by velocity (47.4 km/s) –this analysis creates 3 difficulties for the physics book let's see them

First Difficulty

This analysis tells the space has moving waves are produced by planets motions energies– But- the scientists discovered these waves and they told these waves are produced by the gravitational field- and they called them (gravitational waves)- I prove the sun doesn’t produce a gravitational field and has no massive gravity and no planet moves by the sun gravity – But- here we need to answer (from what source these waves are produced?) because planet motion energy analysis forces us to accept that these waves are produced by the planets motions energies

Here – we need to answer (from what source these waves are produced?)

I prove the gravitational waves are produced by the planets motions energies and not by any gravitational field.

I provided two major proves

(1st proof) I proves there's no gravitational field and the sun has no massive gravity and no planet moves by the sun gravity

(2nd proof) the gravitational waves reflection proves the waves are produced by the planets motions energies because the waves reflection causes effects on the planets data

Second Difficulty

Now we know planet motion energy is stored in the space as moving waves (the gravitational waves)- But- the planets move since long period of time means the planets motions should cause to store massive motion energy in space during this long period- Now -where's this stored massive energy? also the energy can NOT be stored in space forever- so what's happening for this stored massive energy? I prove the sun rays are created from this stored massive energy and not from the sun nuclear fusion process- this is my research hypothesis – in all cases we should know how this stored massive energy be used because this massive energy can cause risk for the solar system stability.

Third Difficulty

Newton Mass gravity definition is disproved by planet motion energy

Because

Suppose the moon moves by the Earth mass gravity and the moon motion produces energy (1/2 mv^2) now let's ask- From What Source The Moon Motion Energy Is Provided? What's the moon motion reason? The mass gravity- means- the mass should provide the motion energy- means – if The moon moves by the Earth gravity that necessitates to decrease the masses of the Earth and the moon by the motion energy- here's the problem- Any Motion Is Done By Mass Gravity Will Cause To Decrease This Mass- this decrease is done because of the motion energy

The analysis tells us–the physicist supposes planet motion produces NO energy this is the only one solution for the problems created by the physicist neglect to observe planet motion energy-

3rdProblem Mass Gravity Force Analysis

The Refutation Of The Sun Gravitational Field

The Sun Doesn't Produce A Gravitational Field Nor Has Massive Gravity – let's prove that in following

(i)

The sun rotation period is (25.4 days– at equator) and (34.4 days – at pole) that shows the sun has no massive gravity nor even ordinary gravity equal any planet gravity otherwise the sun would rotate around its axis in one period of time-

(ii)

No Planet Moves By The Sun Gravity–Newton is wrong- because- Planet moves by the force caused its creation- means- planet creation and motion is done by one force only- otherwise this planet would be broken if two forces have effects on it-

Suppose planet is created (by any force) and the sun gravity attracted this planet and forced it to revolve around the sun by the sun gravity (as Newton imagined) that would force this planet to move against its internal structure and that will cause this planet to be broken-

Imagine a human is forced to walk on his hands in place of his legs- this human will be dead by this motion-

That's why the planet creation and motion is done by one force only- Newton mistake is that he didn't know how the planet is created- and he considered - the creation force is a historical force has no effect on the current motion- Shortly-the sun didn't cause to create any planet and the sun doesn't cause any planet to move

(iii)

We agreed that, mass gravity force can NOT cause any motion- again Newton is wrong- because –any motion will produce energy- suppose the moon moves by the Earth mass gravity- the moon motion produces energy- and – from what source this energy is provided? From the masses of the Earth and the moon –here's the problem

Where Any Motion Is Done By Mass Gravity Will Cause To Decrease This Mass

BUT Mass gravity is a fact - the mass gravity creates a bond between two masses (The Earth and the moon are bond by their masses gravity ) if some outer force causes the Earth to move the moon will move with the Earth and in this case the outer force will provide the motion energy for the Earth and the moon.

(iv)

The planets order contradicts the gravitation equation- for example- Jupiter the greatest mass is not the most near planet to the sun- when we asked the physicist told us this problem is done by (the planets initial conditions)- all these are wrong- planet orbital distance does NOT depend on the sun mass nor on this planet mass- planet orbital distance depends on its neighbor planet orbital distance – my equation proves this fact- let's see it

Planet orbital distance equation (my 1st equation)

d^2= 4do (d-do)

where d=planet orbital distance

do= its neighbor orbital distance

Example (1) Venus orbital distance (108.2)^2 = 4 x 57.9 x (50.3)

d= 108.2 million km = Venus Orbital Distance d0= 57.9 million km = Mercury Orbital Distance

50.3million km=The Distance Between Venus And Mercury Venus Depends On Mercury

Example (2) Saturn orbital distance (1433)^2= 4 x 778.6 x 655

d= 1433 million km = Saturn Orbital Distance d0= 778.6 million km = Jupiter Orbital Distance

655million km=The Distance Between Saturn And Jupiter Saturn Depends On Jupiter

All planets orbital distances are defined based on their previous neighbor planets orbital distances- the equation is correct and discussed in item no. (III)- Shortly- planet mass has no any effect on this planet orbital distance definition.

Notice

Planet orbital distance definition depends on its neighbor orbital distance this fact is proved by many different methods my equation is one method only of them, all these methods don't use any planet mass- all planets orbits are defined based on their neighbor planets orbits (item No. III has more proves)

(v)

Also-Newton told-planet motion depends on its mass- means-planet velocity depends on its mass- this also is wrong - I define planet velocity (my 5th equation)- planet velocity is defined by many rules all of them don't use any planet mass- at all Planet mass has no rule in this planet velocity definition.

The Conclusion

The Sun Doesn't Produce Any Gravitational Field

4th Problem The Matter Creation And Its Nature Definition

In following we compare between the physics book theory about the matter creation and my theory about it- the discussion contains Two points

I- The Physics Book Theory About The Creation of the Matter (Mass)

The Matter Is Created Independently From Any Outer Motion – means- even if the matter motion is stopped the matter is still found and never be perished (the motion here means the outer motion and not the atoms motions)

The Matter Is Motionless By Nature

The Matter Needs Mass Gravity Force To Cause Its Motion

The Matter Data And Dimensions Are Not Changed By Its Motion

The big bang theory tells planet is created by random creation- for example- Jupiter diameter is created by unknown value and Jupiter is collided many times in its history and these collisions caused Jupiter diameter (and mass) to be decreased- based on that– Jupiter diameter value (142984 km) is found by random process and without any geometrical reason behind- by that- the big bang theory prevent us to use any planet data to discover the creation and motion rules of this planet.

Note – The physicist doesn't use planet data in forming a theory to explain this planet motion-for example- Jupiter diameter is 142984 km and the physicist has a theory explains Jupiter motion but if Jupiter diameter is changed into 180000 km the theory will have no change because the physicist doesn't consider Jupiter diameter is a player in its motion- that's why the big bang theory is wrong because it supposes the change in diameter and mass doesn't cause a change in motion

Shortly- the physics book doesn't tell how the matter is created nor what's the matter nature- we remember Einstein problem in physics- he told (All researches in particle electromagnetic properties can't predict this particle behavior in the daily life physics) that shows two different branches of the physics one for the electromagnetism and the other for the mass gravity physics

II- My Theory About The Creation of the matter (mass) –

The Matter Main Features Are:

The Matter Is Created In Pairs Means- No Single Matter Is Created -This conclusion depends on Gamma ray experiment -From Gamma ray (1.2 Mev) electron and positron are created- by this experiment- the matter is created in pairs from electromagnetic waves- the produced pair particles motions depend on each other (or related to each other) (notice the creation system is male and female–two complementary matters-that tells the source of energy must be electromagnetic wave)

The matter is created depending on its motion- means- the motion is found before the matter creation- this conclusion depends on my planet diameter equation because planet diameter is created depending on this planet velocity (for example Neptune diameter is 49528 km because Neptune velocity is 5.4 km/s)- means–Planet motion is defined before its creation -later explained

Lorentz transformation proves Matter dimensions are effected by high speed motion- also- Lorentz transformation proves the matter and space are created from the same energy for that particle length and distance both are contracted by the same one equation (Lorentz length contraction effect)

The Matter Is Created Depending On Light Motion –

The Discussion Proves These Features Strongly

The Matter Creation Depends On 5 Main Facts Which Are

Gamma Ray Can Produce Electron And Positron

Lorentz Transformation

My Planet Diameter Equation

The Coherence Of Light (Young Interference)

Planet Diameter Creation Depends On This Planet Orbit

(Item No. i) Gamma Ray Can Produce Electron And Positron From Gamma ray (1.2Mev) one electron and one positron are created- I prove the matter is created by this method- means- the matter is created in pairs and no single matter is created

(Item No. ii) Lorentz Transformation

Lorentz transformation tells

If a particle moves by high speed motion (near to speed of light), this particle length would be contracted and its mass would be increased and its time would be dilated

I accept this meaning clearly and find this meaning supports my theory strongly BUT Many physics Books tell the following

(NO Real Change Is Done For Any Particle Data Moves By High Speed Motion But All Changes Are Illusions Of Measurements)-

Means- while a particle is moving by high speed motion and the experiments results show contraction in its length and increasing in its mass and dilation in its time – these changes are just illusions in measurements and the particle itself has no change in any data - tenth of books tell this meaning clearly and with confirmation and the physicist killed Lorentz work and made Lorentz transformation measures illusions and not facts- regardless the empirical proves which supports Lorentz transformation

I refuse these books idea because

The Physics Is The Measurements Science And What's Measured Is The Fact

If no real changes are done how the problem of Michelson and Morelly experiment is solved?- also- Why the synchronous events in one frame can't be synchronous in another (as Einstein stated) where no change is found for any data- the distances are Not contracted nor the time is dilated nor the mass is increased why the events can NOT be synchronous in any frame?

If the particle own data is measured correctly while it moves by my motion velocity and these measurements are suffered from illusions because the particle moves by high speed motion relative to my motion that means (I'm the universe reference point)

We notice- Lorentz length contraction equation can't distinguish between particle length and a distance, both can be contracted by the same one equation- that supports my theory tells (Matter And Space Are Created From The Same Energy)–

My planet diameter equation proves planet diameter is created depending on this planet motion and also proves the matter and space are created from the same one energy which supports Lorentz transformation

NOTICE

The major importance of Lorentz transformation is

The transformation proves there's a connection between particle dimensions and its motion means the motion has effect on particle dimensions definition and by that the matter (mass) can't be independent because its existence depends on a motion- shortly (The Matter Existence Depends On Its Motion)

The matter and space are created from the same energy- because- particle length and the distance both are contracted by the same equation (Lorentz length contraction effect) shortly (Matter And Space Are Created From The Same One Energy) (This theory is proved by my planet diameter equation)

(Item No. iii) My Planet Diameter Equation

My Planet Diameter Equation (v1/v2)= (s/r)= I

v = Planet Velocity

r = Planet Diameter

I= Planet Orbital Inclination

s= Planet Rotation Periods Number In Its Orbital Period

v2, s, r and I are belonged to one planet and v1 is belonged to another planet

The planet (v1) is defined by test the minimum error

Earth Equation uses Neptune velocity

Mars Equation uses Pluto velocity

Jupiter Equation uses the Earth moon velocity

Saturn Equation uses Mars velocity

Uranus Equation uses Neptune velocity (As Earth)

Neptune Equation uses Saturn velocity

Pluto Equation uses the Earth moon velocity (As Jupiter)

Example Neptune Equation (89143 /49528) = 9.7/ 5.4 =1.8

89143 = Neptune rotation periods number in Neptune orbital period

49528 km = Neptune diameter

9.7 km/s = Saturn velocity and

5.4 km/s = Neptune velocity

1.8 degrees= Neptune Orbital Inclination

59800 days = Neptune orbital period (and Neptune rotation period =16.1 hours)

Discussion

(1)

The Equation Concept Planet diameter should be a function in its orbital distance –otherwise- this planet would be broken by its motion- BUT- the designer can't create a function has only 2 variables (Planet diameter and its orbital distance)- because– If this planet changes its orbit (orbital distance) its diameter would be broken also because the diameter is a direct function in the orbital distance without any other variables -As A Result- the designer created planet diameter as a function in this planet rotation period and the planet rotation period is created as a function in this planet velocity and the planet velocity is created as a function in this planet orbital distance- by that- the function between Planet diameter and its orbital distance is created but also it contains many variables (rotation period, orbital period and velocity)- by that- if the Planet changes its orbital distance- this planet orbital period, and velocity and rotation period would be changed but its diameter will be saved

(2)

Matter Definition Based On My Planet Diameter Equation

My equation tells, Planet diameter is created depending on its velocity- for example Neptune diameter is 49528 km because it velocity is 5.4 km/s where the velocity is used in the diameter definition equation- means- Planet motion is defined before this planet creation- how can that be possible? let's answer in following

The original energy was in motion and planet matter is created from this moving original energy and planet matter dimensions are defined by this original energy motion features- after Planet creation, the planet moves with this original energy motion means the planet moves this same motion based on which the planet data and dimensions are created that's why Planet data is in full harmony with its motion features- that explains how planet diameter is created based on its velocity

Shortly- the matter is similar to a muscle in a creature- the muscle dimensions depend on the blood motion- similar to that- the matter dimensions depend on this energy motion from which this matter is created-

Also space is similar to the sea of water- and the matter is similar to a whirlpool (vortex) is found on the sea page- the matter creates for itself a distinguished picture different from the space picture and the matter moves by a different velocity from the space motion velocity- as the whirlpool (vortex) on the sea page- it's created by the sea water but it has a distinguish picture from the sea waves and it moves by a different velocity from the sea waves- that explains how the moving energy can effect on the matter creation data- for example- we have a whirlpool (vortex) its diameter is 2 meters- why does this diameter equal= 2 meters? The diameter is created depends on the water motion velocity, pressure, amount and motion angle and many other features of (the moving water)- the moving water creates this whirlpool with diameter 2 meters and as long as the water motion is not changed this diameter will not be changed also- (notice- The Gravitational Waves Prove The Space Has Motion And Not Static)

NOTICE Also (No Planet Moves By The Sun Gravity) Newton is wrong, because planet moves by the energy from which this planet is created- as explained here – means– The Matter Is Not Motionless By Nature- The Matter moves with the energy from which this matter is created-

(3)

Matter Existence Depends On Its Motion

Shortly-if the motion is stopped the matter will be perished- again the matter is similar to a muscle in a creature body- if the blood motion is stopped the muscle will be perished- this is the fact- Based on that- Neptune velocity is 5.4 km/s if Neptune stops its motion Neptune diameter and matter will be perished-

The fact I prove is (The Matter Creation Depends On Its Motion) – Lorentz transformation and my planet diameter equation supports this fact strongly

DEEP DISCUSSION

(4)

The Matter Is Created In Pair And No Single Matter Is Created

Planet velocity is defined based on the rule (v1v2=constant= 322) let's prove that

322 = 47.4 km/s (Mercury velocities) x 6.8 km/s (Uranus velocities)

322 = 35 km/s (Venus velocity) x 4.7 km/s (Pluto velocity) x 2

322 = 29.8 km/s (the Earth velocity) x 5.4 km/s (Neptune velocities) x 2

322 = 24.1 km/s (Mars velocity) x 13.1 km/s (Jupiter velocity)

322 = (17.9 km/s)^2 (Ceres velocity) (Max error 2%)

The idea is understandable – let's summarize it in following

(i)

The planets velocities are created complementary one another based on the rule (v1v2=constant= 322) and

(ii)

Planet data is created depending on its velocity- means- planet velocity is the first data in this planet creation and based on the velocity all other data is created- as we see in the planet diameter equation, planet diameter and all creation data is created depending on this planet velocity- means- based on (v1/v2) but planet orbital distance is defined based on (v1/v2)^2 and planet orbital period is defined based on (v1/v2)^3

Based on this system planet data is created but we know that planet orbital distance is defined before planet creation and based on the orbit, planet velocity is defined and then all data is defined based on the planet velocity-

(iii)

Now the idea is clear- let's summarize it

The planets velocities are created complementary one another based on the rule (v1v2=322) and planet diameter is created depending on its velocity for that reason planet diameter is created complementary to another planet diameter- let's prove that

341.7 million km = Jupiter diameter 142984 km x Pluto diameter 2390 km

341.7 million km = Jupiter radius 71492 km x Mercury diameter 4879 km (2%)

341.7 million km = Saturn diameter 120536 km x 4 Mars diameter 6792 km (4%)

341.7 million km = Uranus diameter 51118 km x Earth radius 6378 km (5%)

341.7 million km = Neptune diameter 49528 km x 2 The Moon diameter 3475 km

Clearly we see the planets diameters are complementary one another- because the matter is created in pairs and no single matter is created

Notice (1)

Suppose the physicist can create a type of single matter which has no complementary can that disprove my theory tells (The Matter Is Created In Pair And No Single Matter Is Created?) NO NEVER

Because- the matter is created from the original energy and the energy uses a system depends on matters in pairs complementary one another- means any type of matter can't be used by the original energy will be neglected and useless because the energy uses matters in pairs

(Item No. v) The Coherence Of Light (Young Interference)

I provide proves tell Gamma Ray and Young experiments are used in the solar planets creation – let's remember these experiments

(1st Experiment) Gamma ray (1.2 Mev) can produce electron and positron

(2nd Experiment) the coherence of light experiment (Young Interference)

Let's provide the proves for the using of these two experiments in the planets creation

Gamma Ray Experiment

There are two facts prove this experiment concept is used in the planets creation

First Fact Planet creation data is defined based on its velocity- this fact is proved by my planet diameter equation because planet diameter is created depending on this planet velocity as explained before (Neptune diameter is 49528 km because Neptune velocity is 5.4 km/s)-means- Planet velocity is the first data in this planet creation process and based on this velocity all planet creation and motion data is created

Second Fact Planet velocity is complementary one another, which is proved by the rule (v1v2= 322 = constant)- that shows the planets data must be complementary one another as I have proved in the diameters values analysis

Shortly – The planets data are complementary one another (similar to the electron and positron are created from Gamma ray)

The Coherence of light Experiment (Young Interference)

There are two facts prove this experiment concept using in the solar system creation

1st Fact

The planets order is typical for Young interference- if we consider planet diameter is equivalent to the fringe breadth by that the planets order be typical for Young interference where the greatest fringe is in the middle (the greatest planet Jupiter) and the fringes breadth is deceased gradually on both sides

(I Proved Mars Original Orbit Was Between Mercury And Venus- so the original inner planets order was Mercury – Mars – Venus – The Earth) which shows gradual decreasing in diameters- the outer planets diameters also is decreased gradually

2nd Fact

There's a coherence of light in the solar system- what does that mean?

Means- while planet orbit has energy of a light beam- another light beam enters this orbit by that there are two light beams in the same orbit- these two light beams create coherence of light- the planets orbits creation explain this fact in details- but here I want to prove this fact by simple direct proof before the planets orbits creation discussion –let's write this proof here

We have seen that the planets velocities are complementary one another by the rule (v1v2=constant=322) and planet all data is created depending on its velocity- by that the planets diameters also follow this rule where (R1R2= constant) as I have proved in my planet diameter equation

Now let's ask – can the planets orbits complementary one another? NO

So- how this rule (v1v2=constant= 322) is found?

By the energy reflection- means- the energy is reflected in the solar system and this reflection of energy causes the velocities to be reflected on one another and that produced the rule (v1v2=constant= 322)

We note the planets can’t be reflected on each other because the planets are connected with their orbits- and the energy reflection needs freedom in motion- means- this reflection of the planets velocities are done by effect of the energy reflection- please note- the energy reflection is a proved fact in the solar system- this fact is proved by hundreds of the planets data because the energy reflection cause effects on the planets data- shortly- the planets data is created by effects of the energy reflection-

Here we see the coherence of light is created because the orbits have energy where the space is energy and (Another energy is reflected and moved through all orbits and caused to create the planets data) by that each orbit has two energies together- I prove both energies are light beams-for that the two light beams create a coherence of light

I want to say- there are two facts prove the solar system has coherence of light which are the reflection of energy and the planets order

The planets orbits creation explain this theory in details I discuss it in item no. (**)

NOTICE

Please Note – I proved Mars original orbit was between Mercury and Venus and Mars is migrated to its current orbit behind the Earth- by that the inner planets original order was (Mercury – Mars – Venus – The Earth) here we see planets diameters are decreased gradually from the Earth to Mercury where Jupiter was the planet beside the Earth- means – the planets diameters are decreased gradually from Jupiter to Mercury- and the outer planets – the planets diameters also are decreased gradually- as I explained – if we compare planet diameter with fringe- the planets order be typical to Young interference – but – the order is reflected each other –let's see that

The inner planets (Mercury – Mars – Venus – The Earth)- the order tells greater diameter necessitates longer orbital distance – but

The outer planets (Jupiter– Saturn– Uranus– Neptune –Pluto)- the order tells greater diameter necessitates shorter distance

Here we see the orders are reflected one another- but in Young interference there's no reflection- I want to say- the planets orders are reflected because of the sun position- if the sun is not found no reflection will be found- that means- the reflection of energy caused to create the sun in the solar system because the sun creation causes the planets order to be reflected one another- my paper proves the sun is created after all planets creation and motion – and the sun is created by the reflected energy

(Item No. vi) Planet Diameter Creation Depends On This Planet Orbit

The solar planets matters and their distances are created from one energy and this one energy is provided by one light beam and this light beam moves by speed = 1.16 million km per second (The speed is proved strongly and decisively)

The light (its speed 1.16 million km per second) built the solar system orbits starting from Mercury orbit toward Pluto orbit- the light created the planets orbits before any planet creation- means- all orbits are created before any planet creation- the orbits are created based on each other (this fact is proved by my planet orbital distance equation) after the light created all orbits and reach to Pluto orbit- the light energy is consumed in the space creation- and the rest energy is found in one light beam its speed is (300000 km/s = the known speed of light)- we understand this is one light beam its speed was 1.16 million km per second before the space creation (In Mercury Orbit) and its speed becomes 300000 km/s after the space creation (in Pluto orbit) as result for the energy consumption in the space creation-

In Pluto orbit - the light could Not move any further to build any more orbits because any additional space creation will consume more energy and that will decrease the light speed to be less than 300000 km/s (the known speed of light) – and – No known light moves by speed less than 300000 km/s – means- the light had no energy to move any further after Pluto orbit- for that- the light returns to its origin point (Mercury orbit) for that the light is reflected with speed (300000 km/s) from Pluto orbit to Mercury orbit passing through the built orbits– no energy is required in this motion for that the light beam moves with speed of light (300000 km/s) till Mercury orbit.

Please note- the light (300000 km/s) is reflected from Pluto to Mercury

The reflection of the light beam (300000 km/s) Caused To Create The Solar Planets

Comments

The light (1.16 million km per second) created the orbits with energy means the created orbits have energies- and each planet orbit energy is less than its previous neighbor orbit because the planets velocities are decreased gradually- almost the energy is less by rate 80% because the velocities are rated with (0.8)

Each planet diameter is created based on its orbit energy- the planet is similar to a tree planted in a ground and the planet orbit is this ground- that's why each planet diameter depends on this planet velocity and orbital inclination- please note Mars diameter equation proves this fact because Mars original orbit was between Mercury and Venus and Mars diameter is created based on this orbit energy and Mars had migrated from its original orbit to its current one behind the Earth but Mars diameter equation still shows Mars original orbital inclination (5.1degrees) while Mars current orbital inclination is 1.9 degrees- Mars diameter is created based on this inclination (5.1 deg) for that this inclination is seen in Mars diameter equation frequently (please review my planet diameter equation)

The Occurrence Of The Coherence Of Light - The light beam (300000 km/s) is reflected and passed through all created orbits- that shows there two light beams are found in the same area (in any orbit)- because in each orbit there's this orbit energy which is found with the orbit creation by the light (1.16 million km per second) for that we say (Space Is Energy) because any orbit has energy found with its creation- and also the reflected light beam (300000 km/s) passed through all orbits- by that- in any orbit there are two different light beams (two different energies) and these light beams create A Coherence together-

The Amazing Coherence Of Light There's a major interesting point here-the light beam (300000 km/s) created a coherence with the light 1.16 million km per second! BUT HOW?? because the light 1.16 million km per second is consumed and its energy is used for the space creation and the rest energy is this light beam moves by known speed of light (300000 km/s)!! how can the light beam (300000 km/s) meet the original light beam the 1.16 million km per second to create this coherence of light?

Please note- the speed 1.16 million km per second is the major used speed in the solar system data- means- the speed 1.16 million km per second is the secret by which the solar system data can be understood because all data is created as function in this speed-I prove that in the next pages- but this information is written to explain that the light 1.16 million km per second is consumed but its energy still works and causes continuous effect- BUT HOW??

Let's write the answer

The light (300000 km/s) is reflected to move from Pluto to Mercury (while the original light 1.16 million km per second moved from Mercury to Pluto) means the light (300000 km/s) moved in opposite direction for the motion of the original light 1.16 million km per second- MEANS- the light (300000km/s) moved in the opposite direction of space to reach to Mercury- BUT NOT ONLY- in fact- the light (300000 km/s) moved also in the opposite direction OF TIME and moved into its own past – and in past – this light beam (300000 km/s) met the original light beam 1.16 million km per second – and in past – the two light beams created the coherence of light and then this coherence of light results have effects on our present time-

Shortly- the coherence of light in the solar system proves the light beam (300000 km/s) moved on the time-axis and this is an empirical proof for the time-axis motion where the light can move simply on the time axis

Notice – this motion can help us to create the time machine- because- if the light can move into the past that means we may use this motion and take photos of the past events and this will be our time machine which can go into the past and make photos and videos for the past events – even the events since thousands of years we can see in videos or in photos – this motion of light can give us a great option to create our machine of time

Notice the original light beam 1.16 million km per second can not move into the future to meet the light beam (300000 km/s) because in future the original light 1.16 million km per second is NOT found because its energy is consumed in the space creation- but- the light beam (300000km/s) can move into the past because in the past the light beam (300000 km/s) was part in the original light beam 1.16 million km per second and by that the two light beams be found in the same time

Notice – we can not travel ourselves into the past- because planet diameter is created depending on its velocity- as proved by my planet diameter equation- means- the matter is created depending on its motion velocity- and the velocity is a motion in defined direction- the light is free in motion and doesn't forced to move in any direction for that the light has this option to move on the time axis but the matter is created depending on a motion in defined direction (no freedom in motion) for that the matter can't move on the time axis because the motion force the matter to move in a defined direction – the matter moved just to the future– and the matter can't move into the past-

Planet Creation Machine Please note–we see the coherence of light is done by the two light beams 300000 km/s and 1.16 million km per second (because the light beam 300000 km/s can reach to the light 1.16 million km per second by moving into its past)- shortly – here we have 2 light beams in any orbit- and these two light beams cause two motions – we can imagine these two motions are perpendicular on each other – this perpendicular motions create a wave and planet is created as a wave (Particle is a wave also)- that explains how the planets are created

Please note- The reflection of energy is very effective in the solar planets data because the reflection of energy caused the planets to be created- the matter can't be created by the energy of any orbit alone but the reflection of energy adds second energy inside each orbit- by that- two energies are found in any orbit (two light beams) by these two light beams the light coherence is created and also the planets are created as waves-that explains why the planets data prove the reflection of energy because the planets are created by this energy reflection- as when we plant a tree we need a ground and we need seeds to be put in this ground- two players- the planets are created by two energies (two light beams coherence) and for that the planets velocities are defined based on the two speeds (300000 km/s) and (1.16 million km per second) as planet velocity definition proves.

Please note the Matter Is Created In Pairs (as electron and positron from Gamma rays 1.2 Mev) – this is the main system of creation but -In planets creation the rule is used with some complex method- the complementary is found for the planets velocities and the planets data is created depending on these velocities- the same concept but the method is more complex- this similar to the creature creation- the cell reproduction is done by split the cell into two new cells- but in higher creatures the reproduction use more complex methods but the cell method is still the base of these complex methods

Please note the previous analysis tries to conclude how the planet matter is created – I put all available facts to reach to this conclusion- the matter real mechanism may be still not clear but many provided facts help to reach to this mechanism- also- we know the main concept behind the matter creation which is (The Matter Is Created In Pairs And Not Single Matter Is Created)

This Concept Is Proved Strongly And Clearly By The Gamma Rays Experiment And The Planets Data

(Item No. vii) The Proves Of The Light Speed 1.16 million km per second

THE SPEED PROVES

In following I prove the speed 1.16 million km per second is found

The paper provides many powerful proves – but - here I refer to 4 proves only

(1st Proof)

Planet Velocity Analysis proves the speed 1.16 million km per second

Data

322 = 47.4 km/s (Mercury velocities) x 6.8 km/s (Uranus velocities)

322 = 35 km/s (Venus velocity) x 4.7 km/s (Pluto velocity) x 2

322 = 29.8 km/s (the Earth velocity) x 5.4 km/s (Neptune velocities) x 2

322 = 24.1 km/s (Mars velocity) x 13.1 km/s (Jupiter velocity)

322 = (17.9 km/s)^2 (Ceres velocity) (Max error 2%)

Discussion

This is one rule used to define planet velocity- we know this rule (v1v2 = constant =322) – other rules are discussed in planet velocity definition- here we ask only

Why the constant is 322?? Because 1160000 seconds = 3600 x 322 hours

Means – for example

Mercury (47.4 km/s) moves in 6.8 hours a distance 1.16 million km – and

Uranus (6.8 km/s) moves in 47.4 hours a distance 1.16 million km-

Means- the light moves 1.16 million km but we see it as 1160000 seconds and based on this period the constant 322 hours is defined and based on this constant the planets velocities are defined- means- the planets velocities are defined as functions in the speed 1.16 million km per second

(2nd Proof) the planets orbital circumferences total is defined by light speed 1.16 million km per second- let's prove that

100733 million km = 86400 seconds x 1160000 km/s

100733 million km = The Planets Orbital Circumferences Total

86400 seconds = The solar day

Means- light its speed 1.16 million km per second passes in a solar day a distance = 100733 million km = The Planets Orbital Circumferences Total

The planets data analysis proves that the solar day is the major period of time in the solar system- that because- all planets rotation periods are defined based on it- the paper proves this fact strongly

(3rd Proof)

The planets orbits and orbital distances are created from the energy of the light beam its speed is 1.16 million km per second- for that- this speed is registered in the distances data – let's prove that in following

Example

778.6 million km (Jupiter orbital distance) = 1160000 km/s x 671 seconds

721 million km (Jupiter Mercury distance) = 1160000 km/s x 629 seconds

Where

671 million km = Jupiter Venus Distance

629 million km = Jupiter Earth Distance

This example tells that

The light (its speed 1.16 million km per second) created the distances based on each other- means

The light uses 671 million km (Jupiter Venus Distance) as a period of time 671 seconds to pass the distance 778.6 million km (Jupiter Orbital Distance)

Also -the light uses 629 million km (Jupiter Earth Distance) as a period of time 629 seconds to pass the distance 721 million km (Jupiter Mercury Distance)

By this method the light (1.16 million km per second) creates the distances based on each other- means – the distances be created in one network and by one design

the previous data is example for so many other distances let's see them in following

(778.6 / 671)= (721/629) = (629/551)= (2x551/940)= (4900/4188) = (5906/5127)= (5127/4437) = (4345/3717)= 1.16

Where

778.6 million km = Jupiter Orbital Distance

721 million km = Jupiter Mercury Distance

671 million km = Jupiter Venus Distance

629 million km = Jupiter Earth Distance

551 million km = Jupiter Mars Distance

940 million km = Earth Orbital Circumference

4188 million km = 2 x 2094 million km (Jupiter Uranus Distance)

4900 million km = Jupiter Orbital Circumference

5906 million km = Pluto Orbital Distance

5127 million km = Pluto Jupiter Distance

4437 million km = Mercury Neptune Distance

4345 million km = The Earth Neptune Distance

3717 million km = Jupiter Neptune Distance

The paper provides so many other powerful proves for the speed 1.16 million km

Notice

(1.16/0.3) x 2π = 24.3

The equation tells, because the solar system is created by light beam its speed 1.16million km per second with its other speed 300000 km/s

For that - the space is created in curved lines (2π) and the time is created based on the solar day (24 hours)- that explains why the planets orbital circumferences total depends on the solar day period

(4th Proof)

300000 = (205.8)^2 x 7.1 where

The 9 planets velocities total 176 km/s and I add the Earth moon velocity 29.8 km/s the total be 205.8 km/s - the unified wave velocity (205.8 km/s)

7.1 is Lorentz length contraction effect produced by speed 99% of speed of light-

Shortly- the reflection of energy causes to square the wave velocity for that the unified wave velocity (205.8 km/s) is squared by the energy reflection

Now (205.8 km/s)^2 = 42354

The rate 7.1 causes to increase the distance from (42354 km) to (42354 x 7.1= 300000 km)- note-although 7.1 is Lorentz length contraction rate but it increases the distances in place of the contraction effect because the reflection of energy causes to reflect the geometrical effects-

shortly the equation (300000=(205.8)^ x 7.1) proves the planets velocities are defined as function in the known speed of light (300000 km/s)

that proves the planets velocities are defined based on the two speeds of light –the known speed of light 300000 km/s and the original speed of light 1.16 million km per second.

NOTICE

Lorentz length contraction effect for a velocity 99% of speed of light (297000 km/s) is (7.1) as seen in the equation but the solar system uses this rate with modification

(7.1/100)+ 1 = 1.0725

And this final rate (1.0725) controls 40% of all planets data (distances, periods, axial tilts and other data)- this effect is a proof for the motion by high velocity because this rate (1.0725) controls 40% of all data in the solar system and no explanation except Lorentz length contraction effect- more proves are in (Item No. 5-6 Can Relativistic Effects Be Found In The Solar System?)

(Item No. viii) Planet creation depends on light motion

The previous analysis proves planet diameter is created depending on its orbit- specifically- planet diameter depends on its velocity and the velocity depends on its orbit- this fact is proved by my planet diameter equation (where planet diameter is created depending on its velocity) and by Kepler statement (Planet orbit defines its velocity) – but-

Why Does Planet Orbit Define Its Velocity?

Where I proved no planet moves by the sun gravity- by that the planet orbital distance has no effect on this planet motion or velocity nor planet mass has any effect on its velocity-So - Why Does Planet Orbit Define Its Velocity? The next data proves there's a connection between planet velocity and its orbit through light motion

DATA

300000 km = 4.7 km/s (Pluto velocity) x 3600 x 17.73

5906 s x 300000 km/s = 1773 million km

300000 km = 5.4 km/s (Neptune velocity) x 3600 x 15.43

5144 s x 300000 km/s = 1543 million km ((5144= 4495 x (1.0725)^2)

300000 km = 9.7 km/s (Saturn velocity) x 3600 x 8.6

2870 s x 300000 km/s = 8600 million km

300000 km = 6.8 km/s (Uranus velocity) x 3600 x 12.26

4085 s x 300000 km/s = 1226 million km

300000 km = 13.1 km/s (Jupiter velocity) x 3600 x 6.36

2120 s x 300000 km/s = 636 million km

Where

5906 million km = Pluto Orbital Distance

4495 million km = Neptune Orbital Distance

2872 million km = Uranus Orbital Distance = 2 x Saturn Orbital Distance

4900 million km = Jupiter Orbital Circumference

Notice

18048 million km (Uranus Orbital Circumference) = 4.4 x 4085 million km

4900 million km (Jupiter Orbital Circumference) = 2.3 x 2120 million km

4.4 = 2.2 x 2 (with 2.3 the error 5%)

Discussion

The data shows each outer planet velocity is related to its orbital distance by effect of the light motion (300000 km/s)- Uranus and Jupiter shows the rate 4.4 which related to Jupiter (3.1 deg Jupiter axial tilt + 1.3 deg Jupiter orbital inclination)- the energy is reflected from Uranus to Jupiter that causes the two planets use the same rate.

The data proves the planets motions depend on light motion and explains how the planet orbit defines its velocity

Notice

0.8 = (27.8 /35) = (24.1/29.8) = (10.8/13.1) = (5.4/6.8) = (17.2/21.4) = 19.8/24)

Where

35 km/s = Venus velocity

29.8 km/s = The Earth velocity

27.8 km/s = The moon velocity

13.1 km/s = Jupiter velocity

6.8 km/s = Uranus velocity

5.4 km/s = Neptune velocity note (10.8 = 5.4)

17.2 hours = Uranus Rotation Period

21.4 hours = 2 x 10.7 h Saturn Rotation Period

19.8 hours = 2 x 9.9 h Jupiter Rotation Period

24 hours = The solar day period

The data shows harmony between the planets velocities and their rotation periods

Third Item - My 5 Equations

My 5 Equations Prove Planets Creation and Motions Data Is Defined By Geometrical Rules (NO Random Creation)-I provide here the three main equations (1st, 4th and 5th) let's refer to them in following

Planet orbital distance equation (My 1st equation)

d^2= 4do (d-do)

where d= planet orbital distance and do= its previous neighbor orbital distance

Example (1) Venus orbital distance (108.2)^2 = 4 x 57.9 x (50.3)

d= 108.2 million km = Venus Orbital Distance

d0= 57.9 million km = Mercury Orbital Distance

50.3million km=The Distance Between Venus And Mercury Venus Depends On Mercury

Example (2) Saturn orbital distance (1433)^2= 4 x 778.6 x 655

d= 1433 million km = Saturn Orbital Distance

d0= 778.6 million km = Jupiter Orbital Distance

655million km=The Distance Between Saturn And Jupiter Saturn Depends On Jupiter

The equation depends on the planets order, just 2 neighbor planets can be used

The equation exceptions are, Earth depends on Mercury Not Venus – and Mars depends on Venus Not Earth And Pluto depends on Uranus Not Neptune

The Equation Concept Support

let's suppose–There's a right triangle by the 3 points The Sun, Mercury and Venus)- by that - Venus angle is (61 degrees) because Venus orbital distance (108.2 mkm) x cos (61) = Venus Mercury distance (50.3 mkm) – and

Earth angle is (51 degrees) because Earth orbital distance (149.6 mkm) x cos (51) = Earth Mercury distance (91.7 mkm) – and

Mars angle is (41.7 degrees) because Mars orbital distance (227.9mkm) x cos (41.7)= Mars Mercury distance (170 mkm)- and

Jupiter angle is (22.2 degrees) because Jupiter orbital distance (778.6 mkm) x cos (22.2)= Jupiter Mercury distance (721 mkm)

Similar to that – Saturn angle is 16.5, Uranus angle is 11.6 deg, Neptune angle is 9.2 deg and Pluto angle is 8 deg- these angles follow the same system

for example -Pluto angle is (8 degrees) because Pluto orbital distance (5906 mkm) x cos (8)= Pluto Mercury distance (5848 mkm) –

NOTICE No. (1)

The right angle and its triangle is (a hypothesis) – but we can prove it's a fact because (v1/v2) = (θ1/ θ2) -means – these angles are rated with their planets velocities – for example (Neptune velocity 5.4/ Pluto velocity 4.7) = (9.2 deg /8 deg)

NOTICE No. (2) these angles are complementary one another for that

940 = 61 x 2 x 8 = 51 x 2 x 9.2 = 41.7 x 22.2

(61 degrees) is Venus angle and (51 degrees) is The Earth angle and (41.7 degrees) is Mars angle and (8 degrees) is Pluto angle and (9.2 degrees) is Neptune angle and (22.2 degrees) is Jupiter angle

DISCUSSION

The equation and angles system data prove the following

(1)

The planets orbital distances are defined based on their neighbors and NO mass is required to define it- Newton is wrong- planet orbital distance is Not defined based on this planet mass (also planet motion doesn't depend on its mass)

Shortly- the mass is not related for the orbital distance definition at all

(2) The gravitation equation is wrong because it contradicts the planets order- for example (Mercury- Venus – the Earth) this order tells more mass needs longer orbital distance while the gravitation equation tells more mass needs shorter distance- clearly the equation contradicts the planets order- also Jupiter the greatest mass is not the more near planet to the sun – when we asked the physicist he told this is happened because of the planets initial conditions- my equation proves no initial conditions have effects on any distance – all distances are defined by the same one rule and the angles system supports the equation concept proves that (the planets orbital distances are defined based on each other and no mass is required in this definition)

Planet Diameter Equation (My 4th equation)

My Planet Diameter Equation (v1/v2)= (s/r)= I

v = Planet Velocity

r = Planet Diameter

I= Planet Orbital Inclination

s= Planet Rotation Periods Number In Its Orbital Period

v2, s, r and I are belonged to one planet and v1 is belonged to another planet

The planet (v1) is defined by test the minimum error

Earth Equation uses Neptune velocity

Mars Equation uses Pluto velocity

Jupiter Equation uses the Earth moon velocity

Saturn Equation uses Mars velocity

Uranus Equation uses Neptune velocity (As Earth)

Neptune Equation uses Saturn velocity

Pluto Equation uses the Earth moon velocity (As Jupiter)

Example Neptune Equation (89143 /49528) = 9.7/ 5.4 =1.8

89143 = Neptune rotation periods number in Neptune orbital period

49528 km = Neptune diameter

9.7 km/s = Saturn velocity and

5.4 km/s = Neptune velocity

1.8 degrees= Neptune Orbital Inclination

59800 days = Neptune orbital period (and Neptune rotation period =16.1 hours)

All planets diameters follow this equation perfectly

Notice

This equation is discussed with matter creation and definition (item no. I) also the equation is analyzed and discussed with all details in the paper discussions

Planet velocity equation (My 5th equation)

Planet velocity definition is important point of study because many planet data is defined based on its velocity- specifically

Planet diameter is defined based on the rate (v1/v2) by my planet diameter equation –discussed before – and

Planet orbital distance is defined by the rate (v1/v2)^2 –and

Planet orbital period is defined by the rate (v1/v2)^3

Please note – Kepler stated (Planet orbit defines its velocity) and it's fact proved by the planets data – but Newton stated Planet motion depends on its mass- this is NOT Fact and Planet velocity is defined without any effect of its mass as the data shows

(I have refuted Newton theory of the sun gravity and his theory for mass gravity)

Now – let's ask - How Is Planet Velocity Defined?

Planet velocity is defined by Five Rules let's see them in following

(i) First Rule

v1v2 = constant= 322 (my 5th equation)

47.4 km/s (Mercury velocity) x 6.8 km/s (Mercury velocity) =322

35 km/s (Venus velocity) x 4.7 km/s (Pluto velocity) x 2 =322

29.8 km/s (The Earth velocity) x 5.4 km/s (Neptune velocity) x 2 =322

24.1 km/s (Mars velocity) x 13.1 km/s (Jupiter velocity) =322 (Max error 2%)

The rule (v1v2=322) tells the velocities are defined in pairs and not individually, each planet velocity has its own complementary- the rule tells the velocities are reflected on one another- the reflection of energy and data is discussed later.

In this rule we interest for the constant (322)- let's ask- why the constant = 322?

The constant 322 depends on the speed 1.16 million km per second because

(1160000 seconds = 322 hours) - Means

Mercury (47.4 km/s) moves in 6.8 hours a distance = 1.16 million km and

Uranus (6.8 km/s) moves in 47.4 hours a distance = 1.16 million km

Shortly -we realize that the constant 322 is produced based on the speed 1.16 million km per second- means- the planets velocities are complementary each other because they are defined as functions in this same speed 1.16 million km per second

(This is similar to electron and positron are produced from Gamma ray, The two particles depend on Gamma energy in their masses)

Based On This Data

I concluded there's a light beam its speed 1.16 million km per second and from this light beam energy the solar system is created- and the planets velocities are defined as functions in this speed 1.16 million km per second and that causes the velocities to be complementary each other-

(Note the speed 1.16 million km per second is proved strongly in my paper)

(ii) Second Rule

v1v2 = 1

The velocity here uses the solar day (86400 seconds) – let's prove that-

Mercury moves per solar day = 4.095 million km

Venus moves per solar day = 3.024 million km

The Earth moves per solar day = 2.574 million km

The Moon moves per solar day = 2.4 million km

Mars moves per solar day = 2.082 million km

Jupiter moves per solar day = 1.1318 million km

Saturn moves per solar day = 0.838 million km

Uranus moves per solar day = 0.5875 million km

Neptune moves per solar day = 0.4665 million km

Pluto moves per solar day = 0.406 million km

AND

0.406 (Pluto velocity) x 2.4 (the moon velocity) = 1 (error 2.5%)

0.4665 (Neptune velocity) x 2.082 (Mars velocity) = 1 (error 2.5%)

0.5875 (Uranus velocity) x 3.024 (Venus velocity)/1.772 = 1 (error 2.5%)

0.838 (Saturn velocity) x 1.1318 (Jupiter velocity) = 1 (error 5%)

(1.772 = π^1/2)

The second rule tells very similar meaning (v1v2= constant= 1)

The data uses the velocities per solar day for that the constant is changed from 322 into 1 but the rule is the same- (v1v2= Constant)

I want to say- the rule (v1v2 = Constant) tells that (The Velocities Are Reflected On Each Other) this conclusion is simple one (A x 1/A= constant=1)

The rule proves the energy is reflected in the solar system and this reflection has effect on the planets data and for that the planets velocities are defined by this energy reflection and the velocities are produced complementary each other as a result.

Notice the second rule causes confusion because the complementary player is changed- for example Pluto is complementary with Venus (in the first rule 35 x 4.7 x 2 = 322) but Pluto is complementary with the Earth moon in the second rule (0.406 x 2.4 = 1) that tells the players are changed which is illogical idea- how can we solve this problem? The third rule solves it – let's see this rule in following

(iii) Third Rule

v1/v2 = 0.8 (based on the planets order)

47.4 km/s (Mercury velocity) x 0.8 = 38 (35 km/s = Venus velocity error 7.25%)

35 km/s (Venus velocity) x 0.8 = 27.78 (The moon velocity)

29.8 km/s (The Earth velocity) x 0.8 = 24.1 (Mars velocity) (error 1%)

24.1 km/s (Mars velocity) x 0.8 = 2 x 9.7 (Saturn velocity)

13.1 km/s (Jupiter velocity) x 0.8 = 2 x 5.4 (Neptune velocity) (error 3%)

6.8 km/s (Uranus velocity) x 0.8 = 5.4 (Neptune velocity)

5.4 km/s (Neptune velocity) x 0.8 = 4.3 (Pluto velocity 4.7 the error 7.25%)

Please note

The error 7.25 is found by the rate 1.0725 – that means

47.4 km/s (Mercury velocity) x 0.8 = 38 = 1.0725 x 35 km/s (Venus velocity)

5.4 km/s (Neptune velocity) x 0.8 = 4.3= 4.7 km/s (Pluto velocity) / 1.0725

29.8 km/s (Earth velocity) = 27.78 km/s (The moon velocity) x 1.0725

We know the rate 1.0725 is found by Lorentz length contraction effect- and we know this rate has effect on around 40% of all planets data – that's why we see this rate has effect on the planets velocities definition-

Let's remember the question-

In the rule (v1v2=322) we found that Pluto is complementary with Venus because

4.7 km/s (Pluto velocity) x 35 km/s (Venus velocity) x 2 = 322

But in the rule (v1v2 =1) we found Pluto is complementary with the moon because

0.406 mkm (Pluto Velocity Daily) x 2.4 mkm (The Moon Velocity Daily) = 1

The question asked – if the planets velocities are defined in pairs complementary each other and not individually how can the players be changed?

The answer tells – the planets velocities are rated by (0.8) based on the planets order means – the moon velocity daily 2.4 mkm = Venus velocity daily 3.024 mkm x 0.8

The rate (0.8) defines all planets velocities depend on each other by order-

Now let's see Planet velocity final definition– because- the definition uses three planets velocities together and not only two – let's put that clearly in following-

(iv) The Planet Velocity Final Definition

(A)

47.4 km/s (Mercury velocity) x 0.8 = 38 km/s (Venus velocity 35 km/s)

Venus moves per solar day 3.024 million km -But

1/3.024 = 0.3307 million km = Uranus moves per solar day 0.5875 million km /1.77

(note 1.77 = π^1/2) and (38 = 35 x 1.0725)

For that

47.4 km/s (Mercury velocity) x 6.8 km/s (Uranus velocity) = 322

(B)

35 km/s (Venus velocity) x 0.8 = 27.78 km/s (The Moon velocity)

The moon moves per solar day 2.4 million km -But

1/2.4 = 0.406 million km = Pluto moves per solar day 0.406 million km

For that

35 km/s (Venus velocity) x 4.7 km/s (Pluto velocity) x 2 = 322

(C)

29.8 km/s (The Earth velocity) x 0.8 = 24.1 km/s (Mars velocity)

Mars moves per solar day 2.082 million km -But

1/2.082 = 0.4665 million km = Neptune moves per solar day 0.4665 million km

For that

29.8 km/s (The Earth velocity) x 5.4 km/s (Neptune velocity) x 2 = 322

(D)

13.1 km/s (Jupiter velocity) x 0.8= 2 x 5.24km/s (Neptune velocity 5.4 km/s error 3%)

Neptune moves per solar day 0.4665 million km - But

1/0.4665 = 2.082 million km = Mars moves per solar day 2.082 million km

For that

13.1 km/s (Jupiter velocity) x 24.1 km/s (Mars velocity) = 322

Shortly

Three planets velocities are defined in each equation- that tells the planet velocity definition is a process more complex than the simple equation (v1v2= constant) (CONT)

Gerges Francis Tawdrous +201022532292

Physics Department- Physics & Mathematics Faculty

Peoples' Friendship university of Russia – Moscow

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frank-olivier · 9 months ago

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The Topological Advantage: How Anyons Are Changing Quantum Computing

The field of quantum computing has experienced a significant paradigm shift in recent years, with the emergence of topological quantum computing as a promising approach to building practical quantum computers. At the heart of this new paradigm is the concept of anyons, quasiparticles that exhibit non-Abelian statistics in two-dimensional spaces. First proposed by physicist Frank Wilczek in 1982, anyons have been extensively studied and experimentally confirmed in various systems.

The discovery of anyons and their unique properties has opened up new avenues for quantum computing, enabling the development of fault-tolerant quantum gates and scalable quantum systems. The topological properties of anyons make them well-suited for creating stable qubits, the fundamental units of quantum information. The robustness of these qubits stems from their topological characteristics, which are less susceptible to errors caused by environmental disturbances.

One of the most significant advantages of topological quantum computing is its inherent error resistance. The robust nature of anyonic systems minimizes sensitivity to local perturbations, reducing the need for complex error correction codes and facilitating scalability. Michael Freedman and colleagues first demonstrated this concept in 2003, and it has since been extensively studied.

The manipulation of anyons through braiding, where anyons are moved around each other in specific patterns, implements quantum gates that are inherently fault-tolerant. This concept was first introduced by Alexei Kitaev in 1997, and has since been extensively studied. The topological nature of braiding ensures that operations are resistant to errors, as they rely only on the topology of the braiding path, not its precise details.

Topological quantum computing has far-reaching potential applications, with significant implications for cryptography, material science, and quantum simulations. Topological quantum computing enables enhanced security protocols, insights into novel states of matter, and more efficient simulations of complex quantum systems.

Prof. Steve Simon: Topological Quantum Computing (University of Waterloo, June 2012)

Part 1

youtube

Part 2

youtube

Tuesday, October 8, 2024

#topological quantum computing #anyons #quantum computing #quantum technology #quantum mechanics #quantum physics #quantum simulations #material science #cryptography #lecture #ai assisted writing #Youtube #machine art

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chimerarachnid · 10 months ago

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Was Forest’s original plan always to project himself into the machine at the end? It’s always his plan, because this is how he gets to actually be with his daughter again, rather than just watch his daughter. The thing that changes for Forest is that he has adhered to a view of quantum mechanics that does not include many worlds. There’s just one world, which means he can recreate his daughter exactly as she was, and rejoin his life exactly as it was without the car crash happening. What he is forced to accept in the end is that there will be versions of him that can experience that, but also versions that will not experience that. So he has a more poignant end result than the one he was looking for.

So even though he believes in determinism, Forest was going to be able to craft a version of reality that was exactly the same except for the car crash, and go there? That’s exactly right. In effect, what he’d be able to do is rejoin that timeline, but not make the phone call to his wife and not, therefore, be the cause of the car crash. And then he’d be able to experience the unfolding of his life exactly as if the thing never happened. And within that state, it would be a world of equal status to the world that you and I are talking in right now. The problem is that the world is not the simple, deterministic world he wants it to be. So he has to accept a different version.

#devs #devs alex garland #alex garland #simulation #emulation #many worlds #theoretical physics #physics #quantum computer #quantum computing #spoilers #devs spoilers #determinism

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aromanrom · 1 year ago

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Quantum Computing Simulator

Introduction There is a ‘new’ repository on GitHub1. It’s not that new, I think I started it in September 2022, but I didn’t add any description on it here. So, here it is now: A quantum computation project. It’s a quantum computing simulator together with many algorithms as examples and tests. It started first as a very simple simulator, one that simply followed the math, with matrices, tensor…

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#computational physics #Fourier Transform #Ising Model #Quantum Physics #simulation

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chimerarachnid · 4 months ago

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I just wanted to add "At the core of Devs is the notion that their Quantum computer could reconstruct the past based on extrapolation from a single point. This is a notion borrowed from French mathematician Pierre-Simon Laplace. In principle, Laplace stated a vast intellect could know literally the state of every object in the universe, from which it could deduce everything that would happen in the future, as well as everything that had happened in the past. But Laplace died on 5 March 1827. His argument was a thought experiment based not on quantum but rather classical mechanics. His profound ‘Laplace’s Demon’ was based on the Newtonian laws of forces balancing and reacting in a deterministic clockwork universe.

One could argue that what is interesting about Devs and real quantum computing is the notion that one might solve problems with an assumption of parallel universes, and not the 19th-century idea that a deterministic universe consists of causal chains that link past, present, and future in an unbreakable bond.

why did no one tell me quantum computers looked like that

#as a species we're not ready for this yet #but at some point... if we unite the two fields #then it's possible #and that power should ideally only be at the hands of a species who are maturely and intelligently able to wield it #simulation theory? sure. go ahead.#science #quantum computing #quantum mechanics

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kamalkafir-blog · 26 days ago

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Applied Scientist, AWS Center for Quantum Computing, Design and Simulation

Job title: Applied Scientist, AWS Center for Quantum Computing, Design and Simulation Company: Amazon Job description: .amazon.com/blogs/quantum-computing/aws-releases-open-source-software-palace-for-cloud-based-electromagnetics-simulations…. We pioneered cloud computing and never stopped innovating – that’s why customers from the most successful startups to Global 500… Expected salary: $136000…

#Applied #AWS #center #cloud computing jobs #computing #Design #quantum #Scientist #Simulation

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greatprinceofabraham · 5 months ago

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#Voyager

#quantumcomputing is "challenging one of #Einstein’s most cherished beliefs about the nature of reality"

Rather than emergent, could #consciousness be a bridge between classical & quantum conditions, perceiving a #simulation as if it is #reality?

https://youtu.be/kqXkB4H--kE?si=64Nli58JVxJc98rs

#quantum computing #consciousness #simulation #reality #albert einstein

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sight-decoding · 5 months ago

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"Quantum mechanical holography perfectly matches the reality conceived by Descartes hundreds of years ago. The frequency Singularity where souls reside is Descartes’ unextended domain of thinking substance, and the spacetime domain (the cosmic hologram) where bodies reside is Descartes’ extended domain of matter. Descartes didn’t know how to get the two domains to interact, but that was purely because Fourier mathematics had not been discovered in his day. Had it been, Descartes, a brilliant mathematician, would have realised instantly that it solved the otherwise intractable problem of how to get unextended mind to interact with extended matter. Mind is simply the Fourier frequency domain, and matter the Fourier spacetime domain, and they communicate and interact via wellknown Fourier mathematics.

Holography is often described as 3D photography. Photography – “light writing” – uses normal light, while holography uses laser light. Photography is about using light to write a static 2D representation of an object on a film, while holography is about using light to write a static 3D representation of the whole object on a film. If you add time to holography, you get a moving holograph: a “holomovement”.

Souls are made of light (light being nothing other than mathematical sinusoidal waves). They are natural, inherent holographic light writers. All souls together write the spacetime hologram that we call the material universe.

We live in a universe of ontological holography, where souls made of photons create, between them, a cosmic interference pattern, which we all then interpret as physical reality. In fact, it’s just a Fourier spacetime domain projected from a Fourier frequency domain. The material universe is simply a hologram constructed from an immaterial Singularity of interacting, wave-based minds.

The immortal, indestructible soul is the instrument of ontological holography. Welcome to the holographic soul. Welcome to the holographic World. Welcome to reality."

~ Mike Hockney, 'The Holographic Soul' (God Series book 30)

#wisdom #illumination #illuminism #knowledge #philosophy #Ontology #Ontological Mathematics #God Series Books #pythagorean illuminism #Quantum Computational Cosmos #Holographic Universe #Simulation Theory #Simulácrum

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cosmicportal · 4 months ago

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Zero-point energy is the lowest possible energy that a quantum mechanical system may have. Unlike in classical mechanics, quantum systems constantly fluctuate in their lowest energy state as described by the Heisenberg uncertainty principle.

This is what empty space looks like..

In quantum physics, a quantum fluctuation (also known as a vacuum state fluctuation or vacuum fluctuation) is the temporary random change in the amount of energy in a point in space, as prescribed by Werner Heisenberg's uncertainty principle.

- infinite potential within space.

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littlcdarlin · 4 months ago

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Event Horizon

summary: When you start university to do your master’s in physics, you are more than surprised to meet your professor: Joel Miller, an old friend of your parents' who moved away years ago. word–count: 15k warnings: professor kink, power imbalance due to Joel being reader's professor, illegal relationship (overage & consenting), dbf!Joel, big fat age gap (unspecified but written with early 20s & mid 50s in mind), unprotected piv, just overall daddy issues (no use of the word daddy)

note: Okay, time to tell you I am a big nerd and studied physics in uni. Truth is, I quit to pursue a career in the arts, so my knowledge of masters level physics is...a little rusty. Please be lenient with me if I messed anything up. Also, I know most people hate physics, but I promise Joel makes it hot. Warning: explanation of the Dirac equation as foreplay. Also, I'm European and have no fucking clue how the American education system works but I don't care enough to do research. Enjoy <3333

event horizon noun ASTRONOMY a notional boundary around a black hole beyond which no light or other radiation can escape. a point of no return.

Uni felt different at eighteen, when everything was about moving out, drinking beer at frat parties, and kissing boys who didn’t grow up in the same town you did. It was an exciting time, the degree itself fading into the background of all sorts of new experiences, but now that you’re doing your masters, you plan on focusing on your your grades more than on partying.

You enrolled in a new university, farther away from home, with a better physics program, and although you’ve grown up considerably, you still feel that tingle of anxiety you did when you first walked to your dorm, fresh out of high school. This time you won’t have to share with another student, spending your saved money on a bit of privacy that is a single dorm room, but still, you wonder if you’ll make friends here, or if you’ll spend your night hauled up alone, watching trash TV and crying because you’re lonely.

The room is small, blank, but functional with a bathroom you share with another student and a small kitchenette, and immediately you dream of all the ways you could decorate it. You didn’t bring much, just a big suitcase and a few boxes your Dad dropped off earlier. You feel slightly guilty for leaving your parents behind, but the relief outweighs the guilt – you won’t have to come home every Sunday for dinner, visits will be scarce. You love you parents, but the distance is much needed.

You get to unpacking your clothes, reveling in the fact that you can listen to music without headphones in your very own space. You could do it in your underwear, or naked, you could sing and dance along, and nobody would be bothered by it. It’s going to be a tough two years, the program you chose more than challenging, but a childish sort of giddiness fills you – no roommate to be considerate of, no parents to visit and take care of every week. This time in your life is about you, and only you – your career, but also your well-being. You promise yourself to do what makes you happy, instead of looking out for everyone else all of the time, and you’ll start by ordering Thai food and watching the trashiest movie with the hottest actors you can find on the little flatscreen you brought with you.

***

Your first lecture is Computational Physics – the one you’re looking forward to the least. The reason you decided to study physics at all was the predictable logic behind each problem, but the more you studied, the more complex the problems got, until they were impossible to solve analytically. Now you get to solve fluid dynamic equations and simulate quantum systems on a Monday morning instead of having a peaceful cup of coffee and taking a walk around campus.

The lecture hall is big, and you pick a seat that is neither too far away to be able to read the professor’s notes, nor close enough to immediately be pinned as an over-eager teacher’s pet. In the end, you plop down next to a girl who’s sitting alone, something about her shaved head and countless earrings making you think she wouldn’t make fun of you even if you didn’t understand a single thing all lecture.

"Okay if I sit here?", you ask somewhat timidly, trying hard not to sound too much like an eleven year old Ron Weasley boarding the train to Hogwarts.

"Please," the girl answers, "I don’t know anybody here."

"Did you move here, too?"

"Yeah, I’m from New York."

"You look it," you say with a smile, eyes drifting over her clothes and jewelry.

"Thanks…I guess?", she answers, her grin revealing a charming gap between her front teeth. "I’m Alva."

You introduce yourself, thankful to have found someone you can stick to already. Throughout the lecture you find out that apart from being much cooler than everyone else in the room, Alva has a biting sense of humor, and a near endless knowledge of computational physics. You make a mental note to ask her to study together, her explanations much easier to understand than the professor’s.

The two of you spend your lunch break together, and you tell her a little bit about yourself, but way too soon it’s time to go already – you have Advanced Quantum Mechanics in a different lecture hall. This you find way more interesting, basic quantum mechanics was one of your favorite lectures during your bachelor’s degree. As Alva and you sit down, you find yourself hoping you’ll be able to help her out this time, or you’d feel like a leech for making her help you with Computational. She doesn’t seem bothered, though, and keeps babbling happily about a band she recently discovered.

"– Britpop, but they only put out two albums. I think they were like a student band or something? They’re wildly underrated, I’ll send you a song, their debut is called The Sun Is Often Out."

Your thoughts start to wander off a little, eyes drifting over the old-fashioned chalkboards, when the door at the front of the lecture hall opens, and a tall man walks in – a man you recognize.

"Holy shit," you whisper, interrupting Alva’s rant about the Longpigs, and she turns her head to look at what you’re staring at.

"Damn," she says with a grin, "if I wasn’t gay, I’d want a piece of that."

"No," you snort, "I know him. He’s my Dad’s friend."

Alva opens her mouth to say something, but at that moment, Joel Miller steps forward, checking to see if the microphone is working, and introduces himself to the hundreds of students in front of him. His voice is deep, and as warm as you remember it, but that’s where the accuracy of your memories ends – your childish brain failed to register the tanned forearms and rolled up sleeves, the carelessly styled curls, the perfect side-profile. He’s got grey streaks in his hair now, which should send you into a crisis about time passing and your own little life being finite, but instead it makes your stomach swirl with something dangerous. Joel Miller, the Joel Miller, who organized backyard barbecues with your father and bought your favorite vegan sausages when your Dad rolled his eyes at you, who made strawberry lemonade instead of lemon, because he knew you preferred it, who helped you with your physics homework when you were graduating high school and didn’t rat you out when he caught you smoking at seventeen – he’s handsome.

There’s still a familiarity about him, the way he moves and talks, although it’s unsettling to see him in such a different environment. You’re used to band-tee-Joel, beer bottle and tongs in his hands, a breezy smile on his face. He looks different here, in a white button-down, with a stern expression on his face, as he’s reading the names on his list to check attendance. When he calls Alva’s name and she raises her hand, his eyes flicker upwards, but he doesn’t look at you. Still, your stomach lurches. If you listen carefully, you can detect that southern twang in his voice you’re sure most people would miss, and it fills you with satisfaction to know you’re the one who knows him best in this room – you’re sure half the lecture hall must see how attractive he is.

When he reads out your name, there’s a surprised lilt to his tone, and your heart threatens to skip a beat.

"Here."

Your eyes meet, and although his expression doesn’t change, he holds your eyecontact for a second too long. Alva nudges your side and grins.

Your plans about outshining Alva and returning the favor of helping with a lecture are quickly buried by Joel Miller’s beautiful hands – thick fingers holding a piece of chalk almost tenderly, twirling it around when he isn’t writing on the chalkboard. You vaguely register him introducing the Dirac equation, but as interesting as you would normally find it, your thoughts are stuck between memories of barbecues and the realization that you will have to call the man who taught you to drive Professor Miller.

If Alva notices your wandering mind, she doesn’t comment on it, which you’re thankful for. You do notice her throwing you a couple of knowing glances, as you copy down what Joel is writing down, mixing up gamma, delta, and the Dirac spinor.

"Alright, so you all know how Schrödinger’s equation works great for quantum mechanics, but it doesn’t play nicely with Einstein’s relativity, right? That’s a problem because electrons move fast, sometimes close to the speed of light, so we need an equation that respects both quantum mechanics and special relativity. That’s where Dirac steps in."

He’s still got that warm way of explaining things your Dad never managed when you needed help in high school, like he enjoys clearing things up for people. He’s a born teacher, patient when you panicked in the car because you confused the clutch and the break, persistent when you wanted to throw your physics book against a wall. Look, kid, think of it this way: Push harder, it moves faster. Make it heavier, it’s harder to move. If you apply a force F to an object with mass m, it will accelerate a. That’s why your Dad’s car takes longer to stop than your bike. Even now, he manages to make a far more complex equation than Newton’s second law tangible.

"Dirac's equation is like the grown-up version of Schrödinger’s equation. It explains how particles with spin-half, like electrons, behave when they move at relativistic speeds. The gamma mu matrices make sure the equation works in four-dimensional spacetime, meaning three space dimensions plus time. The psi is a spinor, which is just a fancy way of saying that an electron isn’t just a simple wave function, it actually has spin built into its nature. Now, can anyone think of a situation where we would need to use this equation instead of the regular Schrödinger equation?"

Nobody raises their hand, most people still busy with writing down Joel’s complicated notes, and as if on cue, his eyes are on yours when you look up from your notebook. He raises an eyebrow, and you see the corner of his mouth twitch almost imperceptibly. Then, he calls your last name, a formal Miss dripping off his tongue as if he hasn’t called you kiddo for most of your life. It’s almost like he’s making a joke only the two of you are able to understand, and the thought thrills you to your bone. Two can play this game – you smile back.

"Sure, Professor Miller. You’d use it for studying high-energy particles, like electrons in particle accelerators, because it accounts for relativistic speeds. It’s also needed for situations where particles are created or destroyed, which Schrödinger’s equation doesn’t cover."

Again, his eyes linger on yours, and his slightly amused smile turns into a more genuine one at your answer. You let out a relieved sigh.

"Exactly," Joel answers, his attention on the rest of the class again, "Someone payed attention during Basic Quantum Mechanics. Now, here’s where it gets wild. When Dirac wrote this down, he realized it naturally predicts antiparticles, meaning for every electron, there should be a mirror-image particle with opposite charge, which we now call the positron. That was a huge deal because it wasn’t something people were expecting, it just fell out of the math."

For the rest of the class, Joel doesn’t continue that little game between the two of you, but whenever he asks a question, his gaze flickers over you, and your stomach gives an embarrassing little jump. Alva grins whenever this happens, but for most of the class she’s busy following Joel’s explanations.

"I want you to read up on today’s lecture," Joel says at the end of the lecture, and writes down a few page numbers on the chalkboard, "and solve the problems I mentioned earlier. Attendance isn’t mandatory, we’re all adults here, but I urge you to come if you’re interested in graduating in the next three years. Trust me, it’s easier to just do the work here than in your dorms. Now, enjoy the weather, see you Monday."

You and Alva pack up your things, and before she can ask you which class you have next, you pick up your backpack.

"I’m gonna say hi to him," you tell her, nodding in Joel’s direction, "my Dad and him go way back."

"Sure," Alva says, a cheeky smile on her face, "it’d be rude not to."

"Meet you outside?"

"I’ll be at the vending machine. Go get him," she jokes, and you snort.

Joel is packing up his course materials when you make your way down the steps and to his desk, but he looks up when he hears you coming towards him, and immediately his face splits into a smile. If you were anywhere else and ten years younger, he’d probably ruffle your hair.

"Good lecture," you say, "Dad didn’t tell me you’re teaching again."

Joel puts his piece of chalk into a tin box and nods.

"I don’t think he knows. You know how it is, we never get around to callin’ and I haven’t been home in a while."

So this is a new development, perhaps even Joel’s first semester back at university, too.

"What about the contracting? Don’t you miss the…pipes?"

He chuckles at your lack in basic contracting knowledge, his eyes not moving from yours.

"Ah, that was always Tommy, he just needed a little help. Company’s doin’ well now, though, so he’ll manage without me."

You think you remember Tommy – a man good-naturedly chasing you and the rest of the giggling neighborhood kids with a harden hose – but the memory is too vague to be sure it’s really him.

"You’ve grown up," Joel says, almost accusingly, and you shrug and smile. "Doin’ your master’s already. How come you’re familiar with Dirac?"

His accent is much thicker now that it’s only the two of you, and you notice a hint of pride when he asks about your correct answer to his question during the lecture. The satisfied feeling it gives you is still the same as when he high-fived you after your drivers test, or when he patted your back after you solved a problem for school without his help.

"Summer reading," you admit, trying hard not to sound like a nerd, "Basic Quantum Mechanics was my favorite lecture as an undergrad."

Joel smiles at you, and puts his notes into his leather bag. He slings it across his shoulder, and nods towards the door.

"How would you like to grab a coffee and tell me all about what’s been goin’ on with you and your old man?"

Your eyes flicker briefly over his hand, gripping the strap of his bag, and you raise an eyebrow.

"What’s the policy for staff having coffee with their students, Professor?"

Joel holds your gaze, the corners of his mouth twitching.

"I’m actually not sure, Miss, I’ve never had to check before."

He’s playing along, and it feels dangerously blurry – yes, he’s your Dad’s old friend, your childhood neighbor, but it feels like more than just joking around.

"Does that mean I’m your first, then?", you ask, voice sweet and close to flirting now. The smile freezes on Joel’s face, and his gaze becomes almost calculating.

"Am I yours?" he asks you softly, and the double-meaning behind his question isn’t lost on you. You feel a thrilling pang in your stomach – Joel Miller is flirting with you.

***

You do end up getting coffee after you tell Alva you’ll meet her later, Joel reassuring you it won’t get him into trouble, and you’re fascinated to see he still drinks it black. What fascinates you even more is that you remember how he takes his coffee, and you wonder why your brain filed this fact away as important, not to be forgotten.

"So, when did you graduate? Sorry I missed it."

There’s honest regret in his voice, which surprises you. Joel was always a warm person, but you figured he cared for you as much as he would have for any kid living across the street.

"Last June," you tell him, dropping a sugar cube into your cappuccino. "I spent the summer working, and now I’m here."

"How d’you like it so far?"

You give a nervous chuckle, torn between the honest truth and pleasant small talk. You opt for the former – this is Joel, after all, not some stranger.

"To be honest with you, I oscillate between enjoying my freedom away from Mom and Dad, and being scared shitless by starting over somewhere new," you admit, looking at your coffee. You haven’t told people about your fear, and it feels good to finally admit it – the grip your parents have had on you makes your newfound freedom almost uncomfortable.

"What d’you mean, startin’ over?", Joel asks, his voice strikingly gentle. You sigh, and shrug.

"I know the distance is good for me, but it was comfortable, just doing what my parents expected of me. I had good grades, nice friends, and just the right amount of drunken nights for them not to worry about my social life too much," you explain, "and now it’s like…there’s so much room to be someone else, cause they won’t see it anyway."

You look up, embarrassed to have spilt your guts like this, but Joel looks thoughtful, his thumb moving along the handle of his coffee cup.

"Sorry," you mutter, "I know they’re your friends, but they can be…"

"Overbearing?"

You smile at him gratefully and he smiles back.

"Look, I know your parents pretty well. They love you to bits, but as an adult I imagine it must be stiflin’.“

"Yeah," you sigh, grateful for his understanding, "I feel like I don’t know who I am when I’m not…their kid."

Joel nods, and sips his coffee, apparently pondering what you said.

"I promised myself I would only do what makes me happy while I’m here," you tell him sheepishly, as if it’s a secret, and Joel laughs.

"Well, I’m not expectin’ you to hand in any homework, then."

You grin, too, and shake your head. It’s surreal, Joel being your professor, and you wearing your heart on your sleeve for him.

"Don’t worry, Professor Miller, I’m not dropping your class."

"You’d better not, it’d really hurt my feelings," Joel says, eyes trained on yours. Again, that blurriness set in motion by the change of his role in your life: neighbor to professor to – what?

"What about you, though? This your first semester here?"

"Second," he tells you, "but I still don’t feel at home. Once a Texan, always a Texan, I guess."

You cock your head and watch him drain the last of his coffee, the cup tiny in his hands.

"What?" he asks you, curiosity evident in his voice.

"You look so different," you say, and Joel scoffs.

"Well, that’s real nice. Know I’m not thirty anymore, but geez–"

"No," you say with a grin, "it’s not that. I don’t know, I’ve just never seen you teach before. Or dressed this nice – I remember you mowing the lawn in a Fleetwood Mac shirt, not checking attendance in a button down."

Joel’s cheeks go slightly pink, and he scoffs again.

"Well, I can’t show up here in a band tee, can I? Gotta dress the part," he mutters.

"I get it. You suit it," you tell him, if only to see that blush appear on his face again. He looks up at you, holding your gaze for a couple of seconds, then he shakes his head.

"What were the odds of us meetin’ like this, huh? I gotta call your father and tell him."

Something about that bothers you, you’d prefer for your parents not to know. You like sitting here with Joel, reminiscing the old times, without anybody getting a peek in.

"Or not," he says gently, seeing the expression on your face.

"Sorry," you say, "course you can tell him."

"You apologize a lot," he tells you, and you fight the urge to say sorry once again. "It’s okay, I’m not tellin’ anyone, kid. ’S just you n me."

That pang in your stomach again, and you nod.

"Alright," you answer, "just us."

You get a refill for the two of you, and a blueberry muffin to split, which feels strangely intimate, but Joel pats his stomach and jokes about keeping an eye on his figure, so you grin, and ask the barista to cut it in half. Joel asks you about your friends, and you tell him about Alva.

"Oh yes," he says and swallows a bite of the muffin, "that punky lookin’ kid who sits next to you?"

"Yeah, she’s nice. Haven’t really met anyone else."

"Geez, I’m not keepin’ you from findin’ frat boys to hook up with, am I?"

You laugh, the idea of sitting here with a twenty-something year old kid named Cole or Josh instead of him so absurd, you can’t help it.

"No," you tell him, "I’m honestly enjoying the fact that I don’t have to have someone else in my dorm anymore."

"Well, that’s a relief to hear," Joel says, "they’re all dipshits."

You remember him telling you something similar about the boys in high school, and it makes you smile. He’s still got that protective streak, then.

"To tell you the truth, I’m glad you’re here," you say quietly, "if I’m not making any friends, I can come crying to you."

Joel watches you for a couple of seconds, not laughing as you intended, but taking your words seriously.

"Course you’ll make friends. Give it a couple of weeks, and you’ll have forgotten all about physics cause you’ll be skippin’ classes left and right to hang out with people."

You don’t tell him, but you think it’s very unlikely you’ll skip any of his classes. Still, you appreciate his words and how confident he seems to be in your ability to open up to people.

"Well, will you give me the answers to your exams if I skip your class?"

"No way," he says with a cheeky smile, the crinkles around his eyes prominent. "I don’t do preferential treatment. You wanna split another blueberry muffin?"

You grin.

"Thought you were watching your waistline."

"I am, that’s why I’m only eating halves."

***

Your afternoon with Joel leaves you on a high for the rest of the day, feeling much less lonely now that you’ve had a conversation beyond the usual so how many siblings do you have? and where did you do your undergrad?

You start spending your lunch breaks with Alva and some friends she made in another lecture, all of whom are very nice. In the evenings you all go to see a movie or have dinner together in any of your dorm rooms, and although you walk around campus holding out one eye for Joel, you don’t see him for the rest of the week. There is always a nudge of disappointment in your stomach, when you glance in the direction of his office, and the door is closed, but you’re so busy, you don’t dwell on it too much. The days pass in a blur of new lectures, swapping music with Alva, and evenings spent as a group of six, and suddenly it’s Sunday again. You aren’t too sad the weekend is already over, and you know exactly why you’re looking forward to Monday, but you don’t allow yourself to think about Joel any more than you can help.

In the afternoon, while you’re doing Joel’s assignment for the next class, your mother calls, and you answer the phone with a mixture of feelings.

Hi, my darling, how are you doing?

"Hi, Mom. I’m good, just doing my work for tomorrow. How are you?"

Good, good. How was your first week? Did you meet anyone nice?

Hah, if she only knew. It feels deceptive, not telling her about Joel, but you like that for now, he’s just yours.

"Yes, this girl called Alva. We and some guys hang out a lot, there’s a cinema near by, but the lectures are pretty hard, so we only have the evenings off."

Well, I’m glad you found some nice people! Dad says hi, he’s making dinner. Anyway, baby, we miss you terribly. Do you know when you’ll be coming home?

"I just got here, Mom."

You sigh so quietly your mother can’t hear it, guilt already nagging at your heart. Sunday is the day you would usually be coming home for dinner, and you know it’s no coincidence your parents called you now.

Of course, you’re right. It’s just not easy for your Dad and me, you know? You’ve never been this far from home, and you’re our baby.

Yeah, you think, your adult baby. You sigh again.

"I don’t know if I’ll come this month, I’m still sort of settling in. But I’ll let you know if there’s a free weekend next month, alright?"

Sure, that sounds great. Will you send us some pictures of your friends, and your room?

"Sure," you say, but it bugs you that you’re giving in. Already, you’re breaking the promise you made yourself, and letting your parents further into your life here than you’re comfortable with.

"Mom, I gotta go, I’ve still got some problems to solve and I’m meeting Alva for dinner soon."

Okay, darling, enjoy your night! And make yourself heard. I love you!

"Love you, too! Talk soon."

Your kind, clingy mother, whose greatest pain is not knowing if you’re safe. In a way you miss her, and you feel guilty for being annoyed. Still, you know you have to gently nudge her away from you, or she’ll suffocate you one day. It makes you angry with yourself, because you know your Mom would have liked nothing more than to hear all about your week, but as soon as she asked you a question, you felt like your seventeen year old self again, getting yelled at because you stayed up past your curfew, and your parents didn’t know where you were.

Tears of frustration spring to your eyes – the mix of feelings too much for you to handle. You wipe them away with the back of your hand, breathe in shakily, and try to focus on your assignment again, but now you’re riled up, and the tears won’t stop.

It’s hard for you to deal with disappointing your parents, forcing them away when they would like nothing more than to know everything that’s going on in your life. So, instead of preparing for Joel’s lecture, you cry on your bed, feeling lonely and angry with yourself for hurting them. You know your reaction is disproportionate, but everything you kept buried while you lived close to your parents comes bubbling out of you.

You call Alva, tell her you have cramps because of your period and just want to stay in bed. She’s understanding, asks you if there’s anything she can do, even offers to bring you takeout or a hot water bottle, which makes you feel all the worse for lying to her. You decline her offer, tell her you’ll meet her Monday morning. In the evening, you regret not letting her bring over a real meal, eating cold pasta in your underwear, tears still running down your face and making your head pound.

***

On Monday, you feel slightly better, your headache is gone and your face isn’t as puffy as you expected it to be. Still, you’re in a solitary mood, and are glad to find Alva is able to keep up an entire conversation virtually by herself – you just grunt from time to time, or give noncommittal movements of your head in vague agreement. You hope if she notices your bad mood, she just thinks it has to do with your period.

Computational Physics is hell – you dislike it on the best of days, but guilt ridden and tired, you’re barely able to pay attention at all, and the professor’s handwriting is so bad, you end up copying down Alva’s notes instead. She’s kind about it, slides over her notebook at an angle that makes it easy to read, and you make a mental note to thank her for being so kind to you while you’re offering nothing but a scowling expression all day. Maybe you’ll cook for her, or make a mixtape of your favorite songs, just to show her you’re interested in being actual good friends.

Lunch passes easily, as always you sit with Alva and the guys, and there’s enough people for you to stare at your mashed potatoes and repeatedly stab them with your fork instead of eating them. They taste like flour mixed up with water, and you dream up your father’s Sunday dinner instead, but it does little to help with the taste.

"So, you lookin’ forward to flirting with Miller in front of the whole lecture hall again?" Alva asks you, as you’re making your way to said room. You glare at her, but can’t help the corners of your mouth twitching.

"Wasn’t flirting with him," you answer, kicking a pebble, "I grew up across the street from him, I’ve known him practically my whole life."

"Whatever you say, grumpy," Alva teases, nudging your shoulder with hers. You’re overcome with a rush of gratitude for the way she treats you, persistently kind and humorous. You chuckle, your mood lifting slightly.

"He’s probably been waiting for you to turn legal," she continues, and you groan.

"Gross, Alva, he’s not a creep."

"I’m just saying, if your little connection gets you the answers to his tests, you could sell them and become rich."

"I already asked him, he said no," you say darkly, thinking of the nights you’ll have to spend studying to pass his exam. This makes Alva laugh her brilliant laugh, and you can’t help but smile, too.

"Damn," she grins, "I’d try if he wasn’t a guy."

You snort.

"You try with Professor Carter, I need the answers to Computational," you suggest, wiggling your eyebrows suggestively.

"You’re joking, but I bet once you get her out of her frumpy cardigans, she’s a real–"

"Okay, stop," you grown, the image of Professor Carter taking off her cardigans worse than her keeping them on – if possible. Alva giggles.

"I’ll help you with Computational," she says, "if you help me with Quantum Mechanics."

"You’re good at both," you argue, and Alva shrugs.

"Not like you, though. I spent like four hours doing Miller’s assignment last night."

You want to tell her you didn’t do it at all, but before you can open your mouth, she spots a friend in the crowd, grabs your arm and drags you over to him.

The three of you sit down together, closer to the front than the week before, which gives you a direct line of sight to Joel’s desk. When he walks in, your stomach jumps – he’s wearing a tie today, a dark burgundy or blue, you aren’t sure from this distance, flecked with specks of white. Again, his hair is styled in that carelessly disheveled look you like so much, and the image of him putting gel in it makes you smile. He gets out his materials for the lecture, and looks up, his eyes finding yours – you smile and he gives a small nod. Again you’re struck by how different he acts in front of the class, how serious he seems. You think of his laid back manner when you had coffee, and struggle to make the images align. Joel clears his throat, and the chatter around you stops.

"Quiet, please, everyone. Thank you. So, last week, we found out that Dirac’s equation predicts the existence of antiparticles. But instead of just accepting that, let’s think deeper—mathematically, what feature of the equation forces this conclusion?"

Joel jumps right into the lecture, and just like last week, nobody raises their hands – you curse the people around you for their lethargy, because sure enough, Joel’s eyes land on you. Before you can shake your head to signal to him not to ask you, he calls your name.

"If I remember correctly, you were already familiar with Dirac’s equation last week. What would you say, what does the existence of negative-energy solutions tell us, and why couldn’t we just ignore them?"

You wish you could answer him, know he asked you because he was sure you’d know the answer, perhaps hoped your enthusiasm for the subject would get the rest of the students to participate more, but you didn’t do the assignment, and you’ve already half forgotten his question. You swallow.

"Um…I…I’m not sure, Sir," you say, watching the way his brows furrow, and looking down at your notes. Alva shoots you a curious look, and when she sees your expression, she raises her hand. You’re thankful to have Joel’s attention diverted, feeling like a fool in front of hundreds of students you’re trying to make friends with.

"Dirac’s equation gives positive and negative energy solutions, and at first, the negative ones didn’t make sense. Dirac suggested they represent antiparticles, like the positron, which he predicted. The idea was that electrons could, like, jump into these negative-energy states, creating a hole that looks like a positron, which was later confirmed experimentally," Alva explains instead of you.

"You're close, but electrons don’t actually 'jump into' negative-energy states. Instead, Dirac proposed that these states are already filled, forming what he called the Dirac Sea. A positron isn’t an electron jumping down, it’s actually a 'hole' left when a negative-energy electron gets excited to a positive-energy state. That distinction is important because it explains why positrons have the opposite charge. Good answer, though, thank you Ms. Bennet."

Joel’s eyes flicker over to you again, but you show no reaction, and he continues with his lecture without asking you another question. Alva glances at you inquiringly, and you sigh.

"I wanted to do the assignment yesterday, but my cramps were really bad," you explain quietly, and she nods sympathetically.

"Call me next time, I’ll send you my answers," she whispers, and you smile gratefully. It seems you really hit the jackpot in friendship when you sat down next to Alva.

***

After Joel’s lecture, you and Alva make your way over to the vending machine, because it has the sour patches she likes, and in her own words she’ll combust if she doesn’t eat some right fucking now.

"Shit," she curses, "they’re stuck."

"Let me," a voice comes from a behind you, and when you turn around, Joel is smiling at the two of you. "Took me a while to figure this thing out, too."

Alva steps aside, and Joel bangs his palm against the side of machine. You jump, but the sour patches make their tumbling way down to the dispenser.

"Great! Thanks, Professor Miller," Alva says, ripping the bag open and offering it to the two of you. To your surprise, Joel takes her up on it, and Alva grins at you.

"You were quiet during today’s lecture," Joel says tentatively, when he’s swallowed his sour patch "everything alright?"

You glance at your shoes.

"Um, yeah. I wasn’t feeling well yesterday, and I left your assignment for last, so…I didn’t do it."

Joel’s expression grows worried, and Alva glances between the two of you.

"Hey, I’m meeting Max for coffee," she tells you, "see you later?"

"Yeah," you answer, grateful she’s granting you this time alone with Joel, "see you, Alva."

When she’s gone, Joel is still looking at you with that worried look on his face, and you sigh.

"Sorry about the assignment," you say, "won’t happen again."

"I’m not worried about the assignment," Joel says earnestly, but then he turns his head, and you know he doesn’t want someone listening in. Sure, you can be seen chatting in the university cafe, but this conversation is rapidly blurring the lines between scholarly and – something else.

"I…have some materials in my office that might make it easier for you to catch up with the lectures again," Joel tells you, and you understand the underlying meaning. Let’s talk in my office.

"Thank you," you say, relieved, and Joel nods, eyes still glued to yours, brows still furrowed. You walk to his office making smalltalk about the lecture, which to anyone listening in would seem like a normal conversation between a professor and an interested student.

Joel opens the door to his office for you, and lets you step in first. It’s small, cramped bookshelves on the walls and a sturdy desk in the middle that is littered with notes, pencils, books, and a couple of old coffee mugs. You notice he put part of his books sideways onto the shelves, which you find weirdly endearing. This is the Joel you know – clutter and warmth.

He closes the door behind you, and you turn around to watch him drop his bag and walk over to the kettle in the corner of the room.

"Coffee?"

"Please," you sigh, "if you don’t have anything stronger."

He raises an eyebrow, but doesn’t answer, just turns on the already filled kettle, and gets two clean cups for the two of you.

"I only have drip coffee," he tells you, "I don’t drink that crap the machines brew up."

"That’s fine, I enjoy the medieval feel of it."

"Watch it," he answers, a smile tugging on his lips, "don’t insult my coffee filter in front of me."

You grin, and walk over to his bookshelf to have a look.

"So, what’s going on?" he asks you while pouring the boiling hot water over the coffee grounds. Again, the Joel you remember – empathetic, but unusually direct. You sigh, turn around and shrug.

"Mom and Dad called yesterday, and I could tell they missed me, but I just…I cut them off after two minutes."

Joel places the cups on his desk, and leans against it. His sleeves are rolled up again, and when he crosses his arms, you feel that familiar pang in your stomach.

"And now I…I don’t know, I feel so guilty, Joel. They’re not even being dicks about it, but I just know they’d prefer for me to check in with them more…and the worst thing is, I know it’s not a big deal. They’ll get over it, they’ve got a good life without me constantly in it, so I don’t know why my stupid brain can’t just let this go, you know? One I miss you, darling, and I’m reduced to this pathetic mess, instead of just, I don’t know, getting my shit together."

You shake your head and clench your teeth, once again embarrassed to come crying to Joel about your parental issues, but he’s the only one you can tell. Sure, Alva would probably listen, but you don’t feel like explaining your family to a near stranger. Joel just gets it. Joel knows you.

He’s looking at you, arms still crossed, and for a second you worry he might not want to hear about your little breakdown, but then he sighs.

"You have your shit together all of the fuckin’ time, kid, I think that might be the problem," he tells you quietly. "You’ve always been so hard on yourself."

He’s right, once again he sees what you struggle to show the world, and his words make tears spring to your eyes. You will your eyeballs to suck them back in, but of course, Joel sees.

"Hey now," he says, taking a tentative step towards you. One tear drops from the end of your lashes and down your cheek, and the dam is broken again – they come spilling in floods. Joel crosses the room in a second, and there is a slight moment of hesitation between the two of you, before you bury your face in his chest, and let your restraint fall. You cry quietly, feel him wrap his arms around you, as he rocks you back and forth.

"You’re alright," he tells you, "Shhh, it’s okay, you’re alright."

"S-s-sorry about the assignment," you manage, and Joel’s hand starts stroking your back.

"Jesus, kid, stop worryin’ about the fucking assignment," he tells you, voice low and worried. "You don’t gotta be so strict with yourself. You’re doin’ just fine."

He smells so much like home, you think you might never stop crying.

"I don’t know what’s wrong with me," you hiccup, "One week here and I’m a mess already."

You feel Joel rest his chin on your head, and his arms tighten around you.

"There’s nothin’ wrong with you, you hear me? You hold yourself to high standards. Creates pressure, kid."

As always, he’s right of course – you want to excel academically, you don’t want to hurt your parents, you want to stay true to yourself and do what makes you happy, you want to make friends without compromising your grades. It’s impossible.

You breathe in shakily, your eyes closed, face buried in Joel’s chest, and for a second he is all that exists – just Joel, all around you, pulling you to the earth. Slowly, your breathing calms, Joel still rocking you soothingly, holding you close.

"There we go," he mutters, when your chest stops shaking, "that’s good."

When you pull away from him, he puts his hands on your shoulders to really look at you, and although you’re embarrassed by your outburst, you’re glad he doesn’t shy away from you.

"I want you to start being a little more lenient with yourself, alright? You don’t need to worry about an assignment on top of everything."

His hands are rubbing your shoulders, his eyes are kind and warm.

"Maybe not about yours, but I have like five other lectures –"

"Okay, so try to stop worrying about my assignments, just mine. Won’t bite your head off if you don’t do them, and I’ll only ask you questions when you raise your hand, alright? In fact, for the rest of the term, I want you to hand them in late."

Despite yourself, your lips pull up in a small smile.

"That’s silly, Joel," you say softly, but he shakes his head.

"It’s not silly, it’s practice to get you out of your comfort zone."

You consider his words for a moment. You do keep a pretty tight reign on yourself, and just the thought of doing every assignment late makes your skin crawl with anxiety. But when will you get another chance to step out of your comfort zone as safely as now, with Joel? He’s offering you a way to try it without actually risking your grades. And who knows, perhaps it actually will take a little bit of pressure off of you.

"Okay," you answer, staring up at Joel with puffy cheeks and teary eyes. "Alright."

He smiles at you, but he still looks worried and you wish he’d pull you close to him again. It’s such a relief to have this sort of human contact with someone who really knows you.

"Feel better?"

You sigh, and nod.

"It’s just a lot, you know, uni and my parents, and every social interaction feels like such a chore, cause I don’t know people yet. I feel like I’m not even relaxed when I’m asleep."

Joel hesitates for a moment, before he speaks, but when he does, he sounds determined.

"Come over tonight, I’ll make us somethin’ to eat, and you don’t have to worry about talkin’ to anyone. We’ll watch whatever you’d like. You still enjoy those crappy horror movies?"

You smile at the shared memory – Joel letting you use his living room to watch slashers your parents didn’t want you to see. One summer, when the heat was so stifling you barely went outside, you practically lived at his place, and when you’d seen all the DVDs he owned, he got you more from the video store.

"I do," you say quietly, the fact that Joel remembers more important to you than his proposal to spend the evening together. You feel significantly less alone, all of a sudden.

"Alright, then. Be over at seven,“ Joel tells you, and you nod, wiping your wet face with the back of your hand.

"Thank you, Joel," you say, and hug him again, because you don’t know how to tell him in words what you’re feeling, and his big, warm body against yours feels more than soothing.

"Course, kid. Just don’t tell Alva, or they’ll fire me."

You smile, your arms still wrapped around his neck, as he holds you.

"But I don’t wanna get you in trouble, what if–"

"No," Joel interrupts you, "no what ifs. No worryin’. I forbid it."

And you accept it, leave it to Joel, because he tells you to – because you don’t have any room in your head for more worries, and because you trust Joel not to do anything reckless. You trust him, period.

***

You text Alva you’re having dinner alone, that your cramps are still acting up, and you do feel slightly bad for lying, but you would never risk Joel’s job. The idea of having dinner with him at his place should make you nervous after your change in feelings about him, but you’re just looking forward to having a meal with someone who knows you, and lets you be yourself.

Joel asked you to be there at seven, so you spend the rest of the afternoon in your dorm room, wondering if you should change your outfit or if it would seem desperate – in the end, you keep the jeans but change into a blouse instead of a sweater. The part of you that stares at Joel’s forearms during class now wants to look pretty for him, so that he’ll ask you over again. You know you’re being ridiculous, but it doesn’t stop you from putting on your nicest perfume.

You’re ten minutes early, so you sit in your little second hand car and try not to panic. You know Joel is merely trying to be a good…friend? Ex-neighbor, Dad’s best friend turned professor? There’s no real etiquette to cling to in this situation, for either of you, and although you’re positive Joel doesn’t have any ulterior motives with you despite his flirting, you know he could lose his job if someone finds out you went to his house. Even if you just watch slashers together the way you did ten years ago. It makes you anxious to know he’d risk something clearly important to him for just that – he moved to a different state, quit his old job, started over completely, and is now willing to endanger that new life just because you’re stressed. At the same time it seems ridiculous anyone could forbid the two of you to spend time together after having known each other your entire life. The thought is absurd, and still, you need to be careful.

You get out of the car before you start to hyperventilate, and ring Joel’s doorbell – it feels strange for him to live in a new house. He opens the door with a smile, and absurd relief floods your veins when you realize he’s wearing an old Led Zeppelin shirt and a pair of worn jeans. This is your Joel.

"I come bearing gifts," you announce, stepping into the house.

“Christ, where did you get this?”, Joel asks, taking the six pack of beer from you, so you can take off your jacket. “I didn’t know they sold Shiner Bock outside of Texas, I’ve been survivin’ on Bud”.

“Brought it with me,” you explain, “figured it’d help if I got homesick, you know, in multiple ways.”

You grin, and Joel shakes his head good-naturedly.

“Old enough to drink, well I’ll be damned. I remember when you begged your Dad to let you have a coke and he asked me if I thought the caffeine would stunt your growth.”

“Did it?”

“It might’ve,” Joel says with a chuckle, “but he didn’t let you have it.”

“Well, he isn’t here now, so let’s put those in the fridge.”

“No," Joel mutters, “no, he ain’t.”

While Joel puts the beer away, you take a look around his living room – despite your reservations about the new house, it reminds you of his old place. It’s got the same masculine and warm feel to it, dark wood, books all over the place, no bells and whistles. Joel is a practical man, and it’s charmingly etched into every part of his life – except for his new work-look. The room isn’t as cluttered as you remember Joel’s old house back in Texas, but you assume he hasn’t had time to accumulate clutter yet. No old newspapers are lying around, no birthday cards stacking up. You wonder if he’s lonely here, teaching all by himself, hundreds of miles away from the place he last grew roots in.

“Do you miss home?” you ask him, when he comes back from the kitchen with two bottles of beer in his hands. He looks at ease, much more himself than back at university. His jeans are faded, his shirt a little too big on his already broad frame, and his hair is clean and curly the way you like it – no gel twisting it into all sorts of un-Joel-like styles. Warmth floods your chest at the sight of him taking a swig of his beer. His crowfeet are a little more pronounced, and his hair has more grey strands than it did back home, but he’s still got that distinctly warm, no-nonsense feel to him.

“Sometimes,” he answers, offering you the second bottle. Your hand brushes his when you take it from him. “But I’m pretty busy here, you know, got a whole lotta lectures to plan, papers to grade and that sort of stuff.”

You nod, and sip at your beer.

“Have you…you know, met people? Made friends here?”

Joel plops down on the couch, and smiles up at you.

“You worried about my social life?”

You shrug, and smile almost timidly.

“You know me, kid, I like bein’ by myself.”

That’s true, for as long as you’ve known Joel, he’s been alone. You know he has nieces and nephews who adore him, and your Dad mentioned a woman once, but it must have been at least twenty years since they were together. You wonder why Joel doesn’t seem to want that sort of a domestic life, surely many women would be happy to let him put a ring on them.

You walk over to the window, and watch a blackbird tug at a writhing worm.

“Have you met someone at uni you wanna be by yourself with?” you ask with a small grin, turning back to find Joel already watching you. “I heard Professor Carter’s still single.”

“She’s very intelligent,” Joel says earnestly. You give him credit for not laughing about his colleague, and suddenly you feel bad for calling her frumpy with Alva. “But I think I’ll leave her to her simulations. Why am I bein’ interrogated?”

“Sorry,” you mumble, and glance out of the window again, “just making conversation.”

“Your turn, then,” Joel answers, and takes another swig of beer. “Any frat boys catch your eye? Or frat girls?”

You glance at him, a smile on your lips, and raise your eyebrows.

“Hey, I don’t discriminate. I thought, maybe Alva…”

“No,” you answer, feeling fond of him for considering the possibility. “Alva’s a friend. The guys are…well, they’re frat boys.”

Your voice carries enough disgust for Joel to laugh.

“Right,” he says, and his eyes are warm when they meet yours again. “Just us two loners, then."

“Cheers,” you say with a smile.

“Cheers.”

***

Joel’s cooking is a mystery to you – he loves to eat, and when he does cook, it’s always delicious, but he only ever makes one of five dishes. Again, that practicality shining through. Why try something new if you’ve perfected your routine? He made pasta for you, wasn’t sure if you’re still vegetarian and makin’ your Dad’s hair fall out, and you smile into the neck of your beer bottle, when you watch him drizzle dressing onto a carefully arranged side-salad. Throughout dinner, you tell him how much you love it at least five times, because you can tell he put effort into the meal. You know it’s not technically a date, but having a dinner he made just for you, in his home – it feels like one.

You steer the conversation away from heavy topics like your parents. Although Joel offered you this evening to make you feel better, you want to spend it with him rather than in your head, so you ask him about books and music, about his lectures, about Tommy and the kids. You like watching how his face lights up whenever he talks about something he particularly loves. Joel is a quiet man, but you found out years ago it isn’t shyness, but a disinterest in most mundane topics – he doesn’t like gossip or superficial small talk. When he tells you Tommy made him godfather of all of his children, the pride is evident in his voice, and you don’t have to fake your enthusiasm, although it amuses you, too – Tommy loving his big brother enough not to consider anyone else.

"She calls me uncle Joe," he tells you with a chuckle, "Can’t pronounce her Ls yet, but I’ve considered legally changing my name."

When you’re done eating, you help him clear the table, but when you reach for the sponge to do the dishes, Joel shakes his head.

"Let me do that later, kid. You wanna watch a movie?"

So the two of you plop down on the couch with a bag of M&Ms and another round of beer, and Joel hands you the remote.

"Go wild," he says, chuckling when you excitedly turn on he TV to open Netflix.

"Wow, a streaming service? I thought you’d just hoard DVDs for the rest of your life."

Joel huffs, and instead of answering, he leans forward, and reaches for something under his couch table. When he turns his head, he’s got glasses on his face, thick-rimmed and black, and so startlingly sexy, you almost drop the remote.

"You…you’ve got glasses?"

"Yeah," he answers, his eyes meeting yours, and you swallow. "When your eyesight deteriorates, that’s when you know you’re gettin’ old."

You hum but don’t answer, just hold his gaze for a second and look back to the screen. You try to ignore the familiar pang in your stomach at the sight of Joel in his new glasses, and skip through movie after movie, mumbling seen it, seen it, that one sucks, seen it, until Joel reaches over and snatches the remote from you.

"Hey–"

"I can’t read anything if you skip through them that quickly."

"You’re not supposed to read, you’re supposed to go with the vibe of the cover."

He glances at you with furrowed brows.

"Okay, sorry, didn’t know you’re a filmbro," you grumble, but it’s almost entirely fake – you couldn’t be annoyed with him, not when he pushes his glasses up his nose, and carefully considers which button to press on the remote.

"I don’t know what that means," he answers, and starts reading the description of a romantic comedy about Christmas.

"I’m not watching that."

"You don’t even know what it’s about."

"It’s September, Joel."

He huffs again, but finally reaches the horror movies. Surprisingly, it doesn’t take the two of you long to pick one, and the thought of two hours of brainless, scary entertainment on a couch with Joel makes you practically melt into his couch.

You can feel Joel’s eyes on you during the opening credits, so you glance over and he smiles.

"Comfy?" he asks, his voice hoarse from relaxation.

"Yeah," you answer, and smile when hands you a blanket. He’s not exactly close to you, but it still feels a little intimate when you spread the blanket out and offer him the other end. He moves over a little, so that the blanket covers his legs, and when you concentrate you can feel his body heat next to you, so you try hard not to – and instead get lost in the movie.

It’s not particularly good, but the story does get under your skin a little, and when there’s an unexpected shriek, you violently jump and instinctively move closer to Joel. He chuckles, but doesn’t give any reaction to your arm suddenly pressing against his. He doesn’t move away, either, so you don’t, fear suddenly not being the only thing bubbling up in your stomach.

"Jesus," you mumble, the creeping music making you anticipate another jumpscare. You’re right, it does come, but prepared though you are, you still wince, and turn away from the screen slightly. Out of sight, out of mind. Joel turns around, too, and when he sees your widened eyes, he grins.

"How’s that Christmas movie lookin’ now?"

"I’m not scared," you say, and there is some truth to it, "I’m just not good with jumpscares."

When the next one comes, you can’t help it, you clutch his arm next to you, your nails digging into his firm muscle, and Joel glances at you again.

"Sorry," you say quickly, letting go of his forearm now marked with five tiny crescent shapes. "Jesus, Joel, sorry."

"It’s fine," he says, and the amusement is evident in his voice, "you sure you’re into this? There might be some cartoons–"

He stops talking when you glare at him, but his mouth is twitching under his beard. You’re determined to watch the entire movie, and you try not to let any reaction show, wanting to prove Joel wrong.

There is one particularly scary scene – it’s not necessarily violent, but the music and shaky camera movements make your pulse race, and you turn your head slightly, so as to look at something else. Joel glances at you again, but he doesn’t laugh this time, just puts a heavy hand on your shoulder. It’s grounding, the warmth of it, how his thumb digs into your muscle and his fingers spread out over your back and neck.

"You don’t gotta force yourself to watch this, kid," Joel says gently, all teasing humor gone.

"No," you say stubbornly, but move even closer to him. His touch is a welcome distraction from the movie, and although you know it’s stupid and reckless, you lean into him, and Joel puts his arm around you. It’s closer than you’ve been to him except for hugging, and your heartbeat starts to quicken for all the wrong, non-horror reasons. When you flinch, Joel tugs you against his side, and it feels natural to hide your face in his shoulder.

He was never touchy with you, or anyone for that matter, so something must have changed. You wonder if he’s trying to comfort you, or if you might not be the only one who can feel that strange pull between the two of you.

When the movie ends, Joel regrettably removes his arm from around your shoulders to switch off the TV, and although you’re slightly disappointed, you scold yourself for expecting something else.

"Not bad," Joel says with a small smile, and pushes his glasses up his nose. "Very brave."

You scoff, but feel the corners of your mouth twitching, too.

"I used to be less of a wimp, but I guess you soften with age."

"You’re twenty-three," Joel argues, "that’s young."

Yeah, too young. Too young to lean over and kiss him, or climb into his lap, or expect anything other than paternal care when he’s got his arm around you. You look at your lap, all of a sudden feeling stupid and silly for having dreamed up an absurd fantasy about the man in front of you.

"Hey," Joel says gently, "what’s wrong?"

"Nothing," you say quickly, "nothing, I had a really great evening. Thanks, Joel."

You can tell you’ve confused him, but he nods, doesn’t question your sudden change of mood, and stands when you get up from the couch.

"Anytime, kid. You call me if you’re havin’ a bad time, alright? My door’s always open."

He’s so kind, so recklessly, stupidly, lovingly kind, and all of it is directed at you. You curse yourself for it, but again you feel that familiar burn in your eyes. Joel reaches out and easily pulls you towards his big body, hugging you the way he did in his office just this afternoon. He doesn’t ask you what brought on your tears, just lets you cry into his Led Zeppelin shirt that smells so much like home, like a childhood you won’t get back to. You remember whiffs of that smell when you were watching movies on his couch while he was at work, too pissed off at your parents to spend the summer at home. This scent was there when you attended a neighborhood barbecue after fighting with your father and Joel grilled some vegan sausages for you without comment or question. He’s always looked out for you like this, quietly, without demanding an explanation, just a solid, comforting presence in your life.

Your tears stop after a couple of minutes, and you take a step away from Joel, wiping your face. He looks so worried again, brows all furrowed and arms hanging limply at his side. Didn’t he flirt with you, though? Didn’t he prepare dinner for you the way a date would, ask you about your dating life, ask you to coffee? You don’t think you would be able to handle another evening like this one not knowing what Joel really thinks, so in a moment of hazy recklessness, you lean up.

His eyes meet yours, all warm and strangely unguarded, but before your lips brush his, a hand on your shoulder stops you. Without saying something, you move away from him, and nod to yourself, his reaction all the information you needed.

"Sorry," you say very quietly, not managing much else now that you’ve humiliated yourself in front of the only person you really know in a six hundred mile radius. Joel runs a hand through his soft hair, and inhales deeply.

"No," he says, his voice a little strained, "no, don’t be. I just…Jesus, kid."

He rubs his palm over his beard in such a familiar way, your chest aches a little. It’s ridiculous how much you want to touch his face, to feel him again, skin on skin. So you don’t turn and run the way your embarrassed heart is telling you to, just watch him collect his thoughts, standing in front of him like a wet and beaten dog.

"Look," he begins, "I won’t say I’m not flattered, but that’s…it’s a bad fuckin’ idea. It’s…it’s chaos, and on top of that most people would argue it’s wrong."

You swallow. You know all of this, have turned it over in your head ever since you stared at Joel’s rolled up sleeves for two hours on that first Monday, but hearing him say it makes your stomach churn.

"Yeah," you mutter, and trace Joel’s shadow with the very tip of your foot, "yeah, of course. Sorry I put you in that position, wasn’t right."

Your face still feels puffy, and you know you’re probably all red and pathetic looking, begging Joel for scraps of his attention, but all of a sudden, he lifts his hand up to your face, and cups it in his broad palm. His thumb strokes your cheek, and when you meet his eye, the expression on his face is tender.

"It’s alright," he tells you softly, "I can see you worryin’ at the speed of light in that pretty head of yours."

Something in your chest flutters at his words, at the rough and warm cadence of his voice. He reads you so easily, one turn of your head and he knows you’re lost to your thoughts.

"I shouldn’t have let myself toy with this idea," he continues, and your stomach flips. "I should’ve realized you’d pick up on it. It’s on me, alright? It’s on me not to start anythin’."

You can hear the implication – I’m the adult here. It’s not what you want to hear, but just the mention of Joel toying with this idea, as he put it, is enough to lift your spirits. So you weren’t crazy.

"I’m an adult," you say weakly, never having felt more like a child. Joel nods.

"You are, but I’m still in a position of power here. Be wrong, to abuse that."

His thumb is still moving over your cheek slowly, making it hard to think straight.

"So dinner and a movie doesn’t abuse it?"

You don’t want to argue, you don’t know why you keep disagreeing with him, and the way his face falls, you wish you hadn’t said it.

"No, it…it does, you’re right. Jesus, of course it does. I don’t blame ya for bein’ ang-"

"I’m not angry," you say softly, and tentatively turn your head in Joel’s hand. You press a kiss to his palm, his warm skin pressed right against your mouth. "I’m not your student, Joel. I mean, of course I am, but I know you. It’s different."

Joel’s eyes are glued to your face, and he looks so conflicted you wish he’d just throw you out of his house, if only to solve his dilemma.

"It’s still wrong," Joel mutters, his eyes glued to your lips since they brushed his skin "even if you take away the fact that I’m your fuckin’ professor. Your Dad…"

"My Dad is half a continent away and finds a way to be unhappy with whatever choices I make, so I might as well make the ones I want to."

The very first day, before you even met Joel, you decided to do what makes you happy while in university, and although this certainly wasn’t what you had in mind, you know it’s what you want. The only thing you want, in fact.

Joel sighs, and tucks a strand of hair behind your ear.

"Joel, I’m not trying to…look, if I’m wrong about this, just tell me, but I feel…I just wanna be close to you all of the fucking time," you say quietly, "and it’s okay if you don’t, really. I just…I want you to know it’s not nothing to me."

Saying I don’t just want to hook up with you would feel too straight forward or crass, but you think Joel gets the gist of what you’re trying to say, and he closes his eyes briefly. You study his face behind his glasses, the wrinkles and freckles from years in the sun. You do feel anxious about his answer, but whatever it is, you’re glad you told him. It’s out in the world now, the way you feel when he holds you, and he can do with it what he pleases – you’ve handed him the reigns.

"I…I know what you mean. Me too," he says very quietly after a beat, his eyes open and looking directly into yours again.

A triumphant pang of affection pulses through you, and you put your hand over Joel’s, which is still resting on your cheek. He looks conflicted, but his other hand holds your waist now, and tugs your smaller body closer to his again. He’s solid as a brick wall in front of you, and you figure you’re allowed to touch, so you rest your hand on his shoulder.

"What am I gonna do with you?" Joel mutters, and strokes your lower lip with his thumb. If you had more guts, you’d let it slip into your mouth, but you’re still afraid he’ll pull back if you make a wrong move, so you just let him caress your mouth tenderly.

"Whatever you’d like," you answer just as quietly, and you know it sounds sexual, but you mean it in every way – if Joel wants to be nothing but your professor, you’d take it, and if he wants to keep you here in his house indefinitely, you’d let him. Joel keeps looking at you, taking you in as if he’s considering whether the risks outweigh whatever magnetic or gravitational pull the two of you have between you.

"Stay," he say after a while, and although his face looks slightly regretful, his voice is determined, "just…sleep here tonight. I like havin’ you here."

You want him to kiss you, to pull you onto his lap on the couch, to take you upstairs right now, but Joel seems to be restraining himself, so you just nod.

"Me too," you whisper, echoing his words back to him, and for just a second, his thumb digs into your lip a little harder, but then he pulls away.

"Testin’ my goddamn restraint," he mutters, and takes a step away from you. "I’ll get you something to sleep in."

***

Joel gets you one of his band tees you love so dearly, and just the idea of being enveloped by something that smells like him all night makes it a little easier when Joel tells you he’ll take the couch instead of inviting you to sleep with him in his bed.

"No," you say softly, "it’s fine, you just sleep in your bed, Joel. I’ll take the couch."

He looks critical, so you offer him a soft smile.

"I don’t know if your back could take it," you tease, and he seems torn up between laughing and frowning. In the end, he just shakes his head, mutters something that sounds a lot like bad fuckin’ idea, and gets you a blanket and pillow.

He brings you a clean toothbrush and towel, let’s you use his bathroom (you look at the shower the entire time you’re brushing your teeth, trying hard not to think about what Joel looks like using it in the mornings), and when you’re done changing, you unlock the door again.

He’s there, sitting on the edge of his bed, his eyes trailing over your form in his much too big shirt. It’s long as a dress on you, coming down to your naked thighs. Joel visibly swallows and gets up from the bed.

"You got everythin’ you need?"

"Yes. Thank you, Joel."

There’s a beat of silence and you almost think Joel’s about to cross the room, but he just runs his palm over his beard the way he always does, and nods.

"Alright. Just shout if there’s…well, you know. I’ll be here."

"I will."

"Alright. Okay…goodnight, kid."

"Night," you almost whisper, voice soft, and right before you reach the door, Joel clears his throat.

"I…you were right about dinner and the movie. I wasn’t just tryin’ to be friendly," he says quietly, and your stomach swirls. Before you can walk over to Joel and do something about it, he sighs.

"Sleep tight, sweetheart."

Sweetheart.

***

You wake to the sound of something dripping, and when your eyes flutter open, you can see Joel’s back from the kitchen. He’s wearing his work outfit again, a white button down and dark pants, sleeves rolled up. It smells like coffee, and with a smile you realize he must be brewing his beloved coffee – no machine, just a filter. He looks broad, even from your spot on the couch, and you enjoy peeking in on him. You study his movements, the way he reaches for a cup, how his fingers absentmindedly drum on the kitchen counter while he waits.

When he turns around, his eyes find yours, and he smiles.

"Mornin’. Did I wake ya?"

"’S fine," you yawn, pulling the blanket up to your chin, not yet ready to get up. "I have classes at ten anyway."

"’S eight," Joel tells you, "Coffee?"

"Yes please," you answer, and stretch your limbs under the blanket.

Joel brings you a cup, complete with a little bit of milk and sugar, and you move your feet so he can sit down on the couch.

"Sleep well?"

You sip your coffee, let it burn your tongue and close your eyes at the taste. When you open them, Joel’s gaze lingers on your face.

"Yeah," you answer, "thank you for…you know."

He nods, takes a sip of his coffee, and looks at his lap. He looks like he wants to say something, but he’s very quiet, and you feel anxiety bubbling up in your stomach.

"Joel, do you want me to leave? It’s fine if you do," you ask him softly, not wanting to make things awkward for him. It would be rational of him to ask you to leave, the smart and ethical thing to do.

"No," he answers quietly, still not looking at you, "I want you to stay."

Stay? On a Tuesday morning, after you almost kissed him and he told you he couldn’t do that, after you spent the night on his couch? When you have classes in two hours, haven’t showered yet, are half naked and wearing his clothes, on his couch under his blanket? When you’ve got friends wondering where you are and probably ten unanswered messages from Alva?

"Alright," you say, agreeing as easy as breathing.

Finally, he looks up, and his expression is so conflicted you reach out for him. Your hand finds his and you squeeze it. He keeps looking at you, his hand limp in your grasp, as if any movement of his muscles would incriminate him.

"You shouldn’t," he tells you earnestly. "Stay, I mean. You shouldn’t stay."

"I know."

You don’t let go of his hand. He doesn’t move his away.

"It’s a really, really bad idea," he adds, and you’re not sure who he is trying to talk out of whatever this is. "It’s risky. Could blow up both our lives."

"Yeah," you say, and watch him sip his coffee, "okay."

Then, a tentative flex of his fingers against yours, and finally, he’s squeezing your hand just as tightly, and before you can process what that means, Joel is leaning over you, dangerously close. Your breathing quickens, you register how soft his hair looks, how strong his hand is. He leans in further and you sit up a little, still cocooned in his blanket. His face is close to yours, his eyes fiery with something you can’t pinpoint, and you sigh, when he closes the gap between you.

He tastes of coffee and toothpaste, and you wish you’d gotten the chance to shower, but the thought disappears almost immediately when you hear Joel groan. His kisses you languidly, deeply, and your fingers come up to his beautiful arm, barely wrapping around half of his biceps. He cradles the side of your face, pulls you closer, makes your stomach clench with need. It feels inevitable, the way he touches you, like you only exist in a physical form to be touched by him.

His free hand peels the blanket off your body, lets it slide to the floor without ever stopping his the kiss, and you moan softly, when his hand touches your waist. The sound makes him break away, stare down at you, pupils blown wide.

"Fuck, you look good in my clothes," he mutters, nudging your jaw with his nose, and pressing a kiss there. "You should really, really go home."

Your head falls back slightly to give him better access to your neck, and he brushes his lips over your pulse point. Your heart skips a beat.

"I – I know," you breathe, fingers digging into his arm. His beard scratches your skin deliciously, and it takes everything in you not to whimper or beg. Joel’s hand slips under your shirt – his shirt – and instead of finding your waist again, he digs his thumb into your hip, stroking the fabric of your cotton panties. The fire in your stomach burns brighter, and you almost buck up into him. Joel Miller, the Joel Miller who until recently had a key to your childhood home, who lent it to you whenever you forgot yours inside – he’s sucking bruises into your skin, and toying with your panties. It’s dizzying, his familiar voice when he hums in satisfaction, even rougher than usually.

His fingers trace the waistband of your panties towards the front, until they find a small, silky bow, and Joel groans. He doesn’t take your underwear off, doesn’t even touch you where you need him the most, just keeps playing with the little bow, until your hips twitch without your permission. A little lower, and he would be able to feel how wet you are, how wet you have been all night. You didn’t do anything about it, not while you were a guest in his house. It would have felt wrong. You can’t imagine anything feeling more right than Joel’s mouth and hands on you, though.

"Jesus," Joel curses, "I should stop bef–"

"No," you whine, all dignity turned to hot air by Joel’s fingers, "please, Joel, please don’t stop."

He curses again, and moves his big body so that he’s not just hovering above you, but actually on top of you, your thighs falling open for him easily. At the movement, his shirt hikes up your thighs, and you know you’re basically on display for him, your soaked underwear leaving little to the imagination. He’s still fully clothed, his perfect button down all wrinkled now.

"Look at you," Joel breathes, lightheaded with desire, "this all for me?"

So he saw, when you moved to accommodate his broad form, saw how soaked you are, knows you ruined your panties just because he kissed you.

"Yes," you breathe, "yes, please–"

Before you can beg further, his finger presses down on your clit, and he watches your face contort in pleasure, as it shoots up your spine. You whimper, staring into his eyes, and he stares right back, as you start to grind your hips against his palm.

Your head feels blissfully empty, all worries about this relationship, uni, your parents, gone from you with a simple, practiced movement of his hand. The whimpers keep falling from your lips, and Joel curses.

"So beautiful," he mutters, "tell me what you need, angel."

It’s not a question, it’s an order.

"I – fuck, I need you i–inside," you groan, and Joel’s lips find yours again.

"Yeah? Need me to fuck you good, even though they’ll throw us both out?"

It shouldn’t turn you on. You’re jeopardizing both your own and Joel’s career, and he’s turning it into dirty talk. Still, your pussy doesn’t lie, and the way it throbs for him, aching to get him inside, makes all doubts disappear from your mind.

"Yes," you answer, unable to say much more as Joel keeps drawing tight circles into your clit.

Your hands drift from his arms towards his front, and Joel curses, when you paw at his belt buckle. It takes you a second, but then it’s open, the sound of the metal exciting you – it sounds like a promise.

Joel finally tugs your panties down, and for a second you’re self–conscious about not being clean shaven, but the second he sees you bare and glistening for him, his fingers dip into your folds, gathering your wetness with no hesitation.

"Fuck me," he groans, bringing his hand up to his face and tasting you, holding eye–contact the entire time, "prettiest pussy I’ve seen in my life."

You twitch under him, dragging your gaze away from his eyes and to his fingers. A moan escapes you, your hands have gone slack on his waistband, and Joel smiles down at you. Then, he does the same motion again, drags the tips of his thick fingers through your sticky arousal, but instead of sucking them clean himself, he holds them up to your mouth. His eyes burn, when you wrap your lips around them without a moments hesitation, and he feeds you your own slick.

"Taste so sweet, huh?"

You don’t answer, just swirl your tongue around his fingers, and suck on them. Joel watches your mouth intently, lets you take your time.

"Good girl," he praises you, and you clench around nothing, "so fuckin’ needy for me."

He drags his fingers from your mouth, and finally pushes into you, the stretch much tighter than with two of your own. Your head falls backwards, and Joel curls his fingers.

"No, baby, look down here," he orders, and immediately you lift your head again, and watch him pump two thick digits in and out of you. It’s dizzying to think it’s the same hand that waved to you from over his fence for years and years. You feel a coil building in your stomach, and you moan.

"Fuck, Joel," you moan, his name leaving a delicious aftertaste in your mouth. His beautiful forearm flexes with every movement, your slick is dripping down his fingers, and those damn sleeves are still perfectly rolled up.

With a few more curls of his fingers, you gush around him, barely having time to warn him, and he praises you, calls you his good girl, drags his fingers against that spongey spot inside of you until you see stars.

When he slips his fingers out of you and holds them up to your face again, you clean them up with your mouth as Joel watches with bright eyes. To think that he’s the same man who taught you Dirac not twenty-four hours ago – already, you want him inside again. When you’re done, he fumbles with his own clothes, and you watch him this time instead of helping.

"You look so good like this," you mumble, eyes raking over his broad form, "Professor."

His eyes snap up to yours, and you grin.

"Fuckin’ Christ, kid," he mutters, popping open the buttons on his shirt, "you can’t say shit like that."

"You don’t like it? You know, I watched you during your lectures and dreamed about…well, about this."

His expression is unreadable, but if you’re not mistaken, his hands move even faster now, and then he shrugs out of his shirt. You almost moan at the sight of his naked torso, so broad and solid.

"You need to pay attention in class," Joel answers, as he opens his pants. Your breathing grows a little shallow when he reveals his boxers underneath, his bulge huge.

"Can’t," you mumble, "not with you looking like this."

He chuckles at that, at the honesty and need in your answer.

"Don’t worry," he says softly, "I’ll fuck it outta you. Won’t be needing’ me in class, not if I’m still leakin’ out of you."

Your lips part, your pussy clenches – a smile tugs on the corners of Joel’s mouth at your reaction. He drags down his boxer shorts, and your eyes snap towards his cock, so thick and dripping in precum. You whimper, you can’t help it, and Joel’s smile widens.

"We’ll make it fit, baby," he says, reading your mind, and then bends down and kisses you again. You try to tug your shirt upwards, but Joel’s hands find your wrists and he holds them tight.

"No, want to fuck you in it," he breathes against your lips, and you press your hips upwards until he groans. He pumps his fist over his cock a couple of times, and aligns it with your entrance.

"Deep breath, baby," he mutters, and you obey, staring up at him as he starts pressing into you. It’s tight, much tighter than his two fingers, and your eyes glass over with pain, but Joel goes slow. His hand strokes your tummy, helps you relax, while he pushes on consistently. You feel like he’s punching the air from your lungs, eyes wide with the stretch of him, as he nips at your jaw and neck to distract you.

"Know it’s a lot, but you can take it, angel."

"Y-yes," you moan, and screw your eyes shut, "please don’t stop, Joel."

Joel’s breathing is ragged with restraint, and suddenly his hips snap forwards – and he’s fully buried inside of your tight body, nestled right against your cervix.

"Back to Joel, are we?" he teases, and gives you a couple of seconds to get used to him. You whimper and claw at his arm.

"I – ah – I’ll call you Professor Miller ’f you want," you slur, as he starts dragging his cock out of you again. You tremble under him, the feeling almost more intense than when he pushed inside of you.

"Yeah? That get you off? Or – fuck– is it the fact that I’m friends with your parents?"

It really, really should be a turn off, to be talking about your parents right now, but the way Joel says it, the way he points out just how debauched it is what you’re doing – you can’t help but moan. You blush, too, can feel the heat in your face, but you’re tired of being ashamed of wanting him the way you do.

"Both," you answer, and this time Joel groans, his hips snapping into you at a rougher pace. The head of his cock hits your spot every time, and you let out little sounds of pleasure with every drag of his cock, unable to form a coherent sentence. Joel’s hand finds your clit again, rubbing circles as his other one pressing down on your stomach.

"Feel that?" he asks you, and you do, you feel him all up in your guts, "you take it so well baby, take all ’f me."

"Yes," you answer, eyes glassy with pleasure, "want all of you, Joel."

He bites your shoulder, keeps rutting into you, and soon you feel another orgasm building.

"Close – ah – so close," you whimper, and Joel speeds up his thrusts just slightly. You clench around him, right on the edge.

"Come for me, angel, give it to me."

You do, your hips bucking, back arching.

"Ah – fuck, Joel, Prof–"

"Say it," Joel orders, fucking you through the waves of pleasure.

"Professor."

He comes, too, twitching deep inside of you and spilling rope after rope of come. It feels right, like you’re his. His groan is rough, his thrusts sloppy, and you feel your pussy spasm around him in a third, weaker orgasm, or maybe it’s just aftershocks from your second. You’re limp underneath him, letting him use your body how he needs to.

"Fuck," he curses, "did so good for me."

He slips out of you, and you can feel his spend drip out of you. You’re weak, soft like jelly, sweaty and entirely satisfied.

"Jesus," you breathe, when he falls down next to you, his couch mercifully being big enough.

"Yeah," he answers, "Jesus."

***

Turns out, Joel Miller is a dirty talking bastard during sex, and a big softie afterwards. He makes you tea, strokes your hair while you sip it, then carries you up to his shower and gently washes your body his his sponge. Throughout, he’s quiet, and you wonder if it was too much, the mention of him being your professor, of your parents, but you’re too afraid to ask. He brushes your forehead with his lips when he dries you off, and pulls another of his shirts over you head. Your panties are entirely ruined, it’s all you’re wearing.

When you’re clean again, and relaxed, Joel pulls you onto his bed, wrapping you up in his arms.

"Did you…was that too much?" he asks you softly fingertips tracing over your thigh lazily.

"It was just right," you answer quietly, and he hums.

"You didn’t feel like you…I mean when you called me Professor, you wanted to do that, right?"

You look up at him, and press a soft kiss against his jaw.

"Of course, Joel. Wanted everything we did, I promise."

He nods, but you can tell there’s still something bothering him.

"You know that’s not what you are to me, though, right?" Your voice is soft. "You’re just Joel."

He brushes the top of your head with his lips.

"I mean it," you press on when he doesn’t answer, "it’s like a costume, Joel. I know it’s your job, but it’s…I don’t think of you as like, an authority figure or something. I just thought you looked hot in that slutty shirt."

"Slutty–?" he sputters and you laugh.

"Sure, you know, with your sleeves rolled up, and that first button popped open."

"’S not slutty."

"You showed your forearms. Half the lecture hall felt like a victorian man seeing ankles for the first time."

Joel makes an exasperated sound, half amused and half offended.

"I mean it," you say again after beat, humor gone from your tone, "and it’s not just sex to me. You know that."

"Yeah," Joel answers slowly. "’S more to me, too."

It’s a hell of an admission.

"What are we gonna do?", you ask quietly, and Joel sighs.

"You’re gonna go to class," he says, voice dark, "and I’ll try very, very hard not to call your father and tell him I’m fallin’ for his daughter."

You bury your face in his chest. With anyone else, it would be too much, too fast, too intense. But this is Joel. It’s not fast if you’ve known him your whole life, is it? You kiss his chest, and he seems to understand.

"We’ll figure it out," Joel says quietly, pressing a kiss to your hair.

For a second you do want your parents to know, want them to see that someone does treat you like an adult, want to look them in the eye and say I’m with Joel now and there’s nothing you can do about it. I have my own life now and it includes this kind man. It’s childish, you know it is. You lean up, catch Joel’s mouth in a kiss.

"Yeah," you answer, “We’ll figure it out, Professor.”

#event horizon #dbf!joel x reader #dbf!joel #dbf!joel miller #professor!Joel miller #professor!joel #joel miller x reader #joel x reader #joel miller smut #joel miller fanfiction #joel x you #Joel Miller x you #joel miller #pedro pascal characters

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itsgerges · 9 months ago

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Best Regards

The Planets Were Moving In Their Orbits Before The Sun Creation (Revised) https://app.box.com/s/dufa274dvpay3fqn6syz6sefjljfwnx9 or https://app.box.com/s/89vxxtv3hc8si245fwxpbw0ts9b126nz or https://www.tumblr.com/itsgerges/762780127698567168/the-planets-were-moving-in-their-orbits-before-the?source=share or https://gerges2022.livejournal.com/239300.html

The Sun Creation The sun is created depending on the planets motions- because- the sun rays is created by the planets motions energies- In details- Planet motion produces energy (1/2 mv^2) and from this energy the sun rays is created- means- the sun is not doing nuclear fusion to produce its rays but the planets motions energies total is used to produce the sun rays– that explains why the sun corona temperature is 5 million Kelvin but the sun surface temperature is 5800 Kelvin- because the energy is not produced from the sun body but the energy comes from out of the sun body (from the planets motions energies total)- This theory is discussed based on 5 hypotheses. The First Hypothesis The Sun Rays Is Created By The Gravitational Waves Motions Energies This Is Extraordinary: Gravity Can Create Light, All on Its Own https://www.msn.com/en-us/news/technology/this-is-extraordinary-gravity-can-create-light-all-on-its-own/ar-AA19YL5d?ocid=hpmsn&cvid=620db4352aa943e2b454919a7b724604&ei=83 This new article tells the gravitational waves can move by speed of light and can produce a light beam- I suppose -the sun rays is produced based on this method by the gravitational waves motions and not by the sun nuclear fusion- also – I claim No star rays is produced by the nuclear fusion process but all rays are created by the gravitational waves motions energies as the article states. The Second Hypothesis The gravitational waves are produced by the planets motions energies- and not by the gravitational field- moreover- The sun is Not producing any gravitational field- The Third Hypothesis The gravitational waves are reflected in the solar system- the wave reflection causes changes for the waves properties and data- the major change is that- the reflection causes to square the wave velocity- means- the gravitational wave moves by velocity (V), if this wave is reflected, it would move by velocity (V^2) after the reflection- The gravitational waves are reflected three times in the solar system- two times in the outer planets and one time only in the inner planets- The Fourth Hypothesis The Planets Motions Use Different Rates Of Time The rate of time use is useful because it enables to accumulate the planets motions energies during a period of time- understandable- Planet motion energy is small energy and the sun rays is massive energy and that necessitates to accumulate the planets motions energies total during a period of time to store motion energy sufficient to be used for the sun rays creation- Shortly- if the planets motions don't use rates of time, no massive motion energy can be provided and for that NO enough energy will be found to produce the sun rays-means- No light beam can be created The rate of time depends on the velocities rate Example (one hour of Mercury clock = 1.6 hours of the Earth clock) because Mercury velocity =1.6 the Earth velocity– the hypothesis is explained and proved in details

The Fifth Hypothesis Neptune Motion Causes Negative Effects On The Sun Rays Production Process are (1) Neptune motion caused the gravitational waves to be reflected two times in the outer planets where one reflection is enough for the required process- the wave reflection is repeated by Neptune negative effect on the solar system motion (2) Neptune caused to decrease the gravitational wave speed by one percent- where the gravitational wave moves by speed of light Neptune caused to decrease this speed by 1% creating a speed = (99% of the speed of light=297000 km/s) and by this speed (0.99C) the relativistic effects are created in the solar system

NOTICE The solar system is one machine performs one Job- and this Job is The Sun Rays Production - All planets motions are used as parts to perform this one Job-

The Sun Rays Production Is Done By Two Basic Tasks (1st task) The Provision Of The Sufficient Energy For The Sun Rays Production- and the sufficient energy is prepared by the motions of the five planets (Saturn- Jupiter- Venus- The Earth- The Moon – and Mars) because these five planets motions are used to create the general rate of time based on which The Sun Rays Are Created. (discussed in details in the 3rd hypothesis)

(2nd task) The mechanism by which the light beam is created- and this mechanism is the relative motion- the gravitational waves move relative to the sun point of space- by this relative motion the sun rays are created- means- the required energy is prepared and provided by the aforementioned five planets- and when the sufficient energy be provided this energy is sent to the planets which create the mechanism and the mechanism uses the sufficient energy to produce The Sun Rays The mechanism depends on the motions of 3 planets (Mercury- Venus and the moon) Specially Venus, because Venus reflects the wave toward Mars and defines its trajectory angle to create the relative motion between the wave and the sun point of space- the relative motion is discussed in details in the explanation of the (first and second hypotheses) The Explanation Of The First And Second Hypotheses

Let's remember The 1st Hypothesis This Is Extraordinary: Gravity Can Create Light, All on Its Own https://www.msn.com/en-us/news/technology/this-is-extraordinary-gravity-can-create-light-all-on-its-own/ar-AA19YL5d?ocid=hpmsn&cvid=620db4352aa943e2b454919a7b724604&ei=83 The article tells the gravitational waves can move by speed of light and can produce a light beam – I suppose (The Sun Rays Is Created By The Gravitational Waves Motions Energies And Not By The Sun Nuclear Fusion -Also All Stars Rays Are Created By This Method And No Rays Is Created By The Nuclear Fusion Process) And –The 2nd Hypothesis The gravitational waves are produced by the planets motions energies- and not by the gravitational field- moreover- The sun is Not producing any gravitational field- The two hypotheses explain how the sun rays creation depends on the planets motions because The Sun Rays Are Produced By The Gravitational Waves Motions Energies as the article states AND The Gravitational Waves Are Produced By The Planets Motions Energies- The two hypotheses are discussed together in 4 Points

First Point (The Gravitational Waves Source)

The gravitational waves are produced by the planets motions energies- and not by the gravitational field- moreover- The sun is Not producing any gravitational field- I provide 2 major proves for this hypothesis which are- (1st proof/ Planet Motion Energy Analysis) and (2nd proof /The Sun Gravitational Field Refutation)

1st Proof / Planet Motion Energy Analysis Planet motion produces energy (1/2 mv^2), Let's ask, where's Planet motion energy? the planet can NOT store its motion energy inside its body because it would raise its temperature and No planet temperature is raised by its motion- logically- the planet motion energy is stored in the space in waves form- means- Planet motion energy creates waves in the space- the planet motion in the space is similar to a fish swimming in the sea- as the fish swimming creates waves in the water the planet motion energy creates waves in the space- let's see this picture clearly- the fish swims because it hits the water by its body and that creates waves in the water- we conclude, the water waves move by a velocity equal the fish velocity because of the reaction force- similar to that- Planet moves in the space and its motion energy creates waves in the space and these waves move by velocity equal the planet velocity- for example- Mercury (47.4 km/s) moves and its motion energy creates waves in the space and these waves move by equal velocity (47.4 km/s)- based on this idea- All planets move and their motions energies create waves in the space where each wave moves by velocity equal its planet velocity – AND I suppose these waves are the gravitational waves AND The planets revolve around the sun in the same one direction and for that their motions energies create waves in the space and these waves move perpendicular on the revolution direction (Toward Pluto orbit) AND In Pluto orbit these waves are unified together into one unified wave- this wave moves by a velocity = 205.8 km/s why? The 9 planets velocities total=176 km/s but I add the Earth moon velocity (29.8 km/s) that makes the total to be 205.8 km/s – I add the moon velocity because the energy is stored finally in the moon orbit- Note- the moon velocity is 27.8 km/s BUT the Earth and the moon revolve around the sun together for that the moon velocity should be considered equal the earth velocity relative to (the sun) – The 1st Proof Conclusion The Planet Motion Energy Creates Waves In The Space Means - The Space Must Have Moving Waves Now -the scientists had discovered waves in the space- And- they considered these waves are produced by The Sun Gravitational Field – BUT Why? The planet motion energy analysis proves the waves must be produced by the planets motions energies- Now let's refute the sun gravitational field theory- the refutation gives support for the conclusion that – the gravitational waves are produced by the planets motions energies and NOT by the gravitational field because there's NO Gravitational field.

2nd Proof / The Refutation Of The Sun Gravitational Field The Sun Doesn't Produce A Gravitational Field Nor Has Massive Gravity – let's prove that in following (1) The sun rotation period is (25.4 days– at equator) and (34.4 days – at pole) that shows the sun has no massive gravity nor even ordinary gravity equal any planet gravity otherwise the sun would rotate around its axis in one period of time- (2) No Planet Moves By The Sun Gravity – Newton is wrong- because- the planet moves by the force caused its creation- means- the planet creation and motion is done by one force only- because- if two forces have effects on the same one planet this planet would be broken- now- suppose the planet is created (by any force) and the sun gravity attracted this planet and forced it to revolve around the sun by the sun mass massive gravity (as Newton imagined) that would force the planet to move against its inner creation and will cause this planet to be broken- this is similar to a human is forced to walk on his hands in place of his legs and when this human refuses to do that (they told him we can force you by our power) for that this human walk on his hands forcedly and later this human is dead by this motion- shortly- the planet is NOT broken by its motion because the planet creation force is the force causes this planet motion- it's one force caused the planet creation and motion- Newton mistake is that he didn't know how the planet is created and by that he didn't realize that planet creation and motion are done together by the same one source- simply- the sun didn't cause to create any planet and for that the sun doesn't cause any planet to move- this analysis shows logical base but left us with puzzles to know (by what rule the planet moves?) and (Why is the sun found in the solar system if it doesn't cause the planets motions?) these questions are answered in the paper abstract and discussions. (3) The mass gravity force can NOT cause any motion- again Newton is wrong- the mass gravity creates a bond between two masses- (the Earth and the moon are bond by the mass gravity)- by that they are similar to a lorry and its trailer – if the lorry moves the trailer will move with the lorry- but the mass gravity can NOT cause any motion- why? suppose the moon moves by the Erath gravity force- the moon moves and produces energy (1/2mv^2) and we have to ask from what source this energy will be provided?- from the mass itself- means if the Earth causes the moon to move the Earth and the moon masses should be decreased by the motion energy- this is a wrong definition for the mass gravity- the mass gravity creates a bond between two masses (The Earth and the moon) if some outer force causes the Earth to move the moon will move with the Earth and in this case the outer force will provide the motion energy for the Earth and the moon- (4) The planets order contradicts Newton gravitation equation- where- the gravitation equation tells (greater mass necessitates shorter distance)- clearly- Jupiter the greatest mass is not the most near planet to the sun- means- the planets order contradicts the equation- when we asked the physicist told us this problem is done by (the initial conditions)- all these are nonsense clearly- planet orbital distance does NOT depend on the sun mass nor on the planet mass- planet orbital distance depends on the neighbor planet orbital distance – my equation proves this fact- let's see it Planet orbital distance equation (my 1st equation) d^2= 4do (d-do) where d= planet orbital distance and do= its neighbor distance

Example- Venus orbital distance (108.2)2 = 4 x 57.9 x (50.3) d= 108.2 million km = Venus Orbital Distance d0= 57.9 million km = Mercury Orbital Distance 50.3million km=The Distance Between Venus And Mercury Venus Depends On Mercury

All planets orbital distances are defined based on their previous neighbor planets orbital distances- the equation is correct perfectly and all planets orbital distances are defined by it- my paper tests and discusses this equation Shortly- planet mass has no any effect on this planet orbital distance definition. Notice Planet orbital distance definition depends on its neighbor orbital distance this fact is proved by many other different methods my equation is one method only of them, all these methods don't use any planet mass- all planets orbits are defined based on their neighbor orbits- (Please note- Newton gravitation equation is wrong- I don't critic it by many critics to short the discussion- but- the fact is that- the light beam created all planets orbits before any planet creation- the light created each planet orbit depends on its neighbor orbit- I prove this fact in the paper discussion- logically this fact kills the gravitation equation because the orbit is created before the planet creation) Notice -Newton is so far from the truth- let's give one more example- Newton told us planet moves by the sun mass gravity- the fact is that- the Sun itself is created by the planets motions energies- that's why Newton ideas are not interesting for discussion because his ideas are imaginary have no part of truth- (5) Also-Newton told-planet motion depends on its mass- means-planet velocity depends on its mass- this also is imaginary idea- I define planet velocity in the explanation of the 3rd hypothesis- planet velocity is defined by many rules all of them don't use any planet mass- at all Planet mass has no rule in this planet velocity definition.

The 2nd Proof Conclusion The Gravitational Waves Are Produced By The Planets Motions Energies And Not By The Sun Gravitational Field- Also-There's No Gravitational Field At All

Second Point (The Gravitational Waves Nature Analysis) Let's ask (1) If The Gravitational Waves Are Produced By The Planets Motions Energies- How Can The Gravitational Waves Move By Speed Of Light While The Planets Move By Low Velocities? Or Generally– regardless the gravitational waves source- how can the gravitational waves move by speed of light? From where the energy is provided to enable the waves to move by the speed of light? (2) Can the gravitational waves be reflected in the solar system? what's the result of this reflection on the waves properties, features and nature? (3) Can the gravitational waves energy be increased? Means can one gravitational wave move by low velocity and this wave motion is accelerated to move by high velocity motion? again from what source the energy is provided and how the acceleration is done? (4) If the gravitational waves are produced by the same gravitational field (The physics book states "the gravitational waves are produced by the sun gravitational field") does that mean all gravitational waves move by equal velocities? can some waves move faster than the others? why and how? (5) If the planets data are reflected on each other – can we discover the geometrical reason behind this features? Planet velocity is example where the velocities are defined by the rule (v1v2= constant) this rule tells the velocities are reflected on one another- why the velocities are reflected on each other? what's the geometrical reason behind? suppose the gravitational waves are reflected in the solar system, why this cause the planets data to be reflected on each other?

(6) If The Gravitational Waves Move By Speed Of Light- How Can These Waves Produce A Light Beam? Because the light beam production needs the value (C^2= squared speed of light) but the waves moves by speed of light only (C=300000 km/s) how the value (C^2) can be produced by the waves motions? (7) If the gravitational waves produce a light beam, does that mean the waves use electric field to produce this light beam? Is there another method to produce a light beam doesn't use electric field or charges? (8) If the gravitational waves are reflected in the solar system can we discover that? can we prove that? and can we know in what planet orbit the reflection is done and if the waves are reflected many times?

The Gravitational Waves Properties, Features and nature Here I compare between the two theories about the gravitational waves source and their effects on the waves properties- 1st Theory (The Physics Book Theory) The physics book states, the gravitational waves are produced by the sun gravitational field- this theory tells little about the gravitational waves properties and nature because the mass gravity concept is puzzled and not understood for that the waves properties and features are puzzled also- let's test this idea- In The Sun gravitational field theory no one knows how the mass gravity force works and if the gravity needs time to work- or if the gravity creates a geometrical design to practice the effect of one mass on the other- the mechanism is not clear and for that the gravitational waves are not clear- for example – no one knows why the gravitational waves can move by speed of light or what waves move by this speed and in what planet orbit or if the wave motion velocity is accelerated gradually from low velocity to high velocity– we shortly know nothing about these gravitational waves- let's ask more questions- are these waves reflected and what's the result of this reflection on the waves properties and nature- where do these waves go? And what's the useful result of these waves energy? can these waves energy be used at all? are there just moving energy in space without an useful goal or result? And The new article tells the gravitational waves move by speed of light can produce a light beam? How these waves can produce a light beam by their motion? DEEP ANALYSIS I wish the respectful reader notices the major change in vision by this article-because- the physics book states the sun rays is produced by the sun nuclear fusion- here- the source of energy is the sun mass and the used method is the sun nuclear fusion- and the light beam is produced Let's put the new article here again This Is Extraordinary: Gravity Can Create Light, All on Its Own https://www.msn.com/en-us/news/technology/this-is-extraordinary-gravity-can-create-light-all-on-its-own/ar-AA19YL5d?ocid=hpmsn&cvid=620db4352aa943e2b454919a7b724604&ei=83 The article tells, the gravitational waves can move by speed of light and can produce a light beam- the light beam is created by the gravitational waves motions- the article tells- the light beam can be produced by the Motion Energy – The article tells (The High Velocity Motion Can Produce A Light Beam)- here the article removed simply The Sun Nuclear Fusion Machine- the whole machine be useless because the light beam can be produced by (the motion energy)- I wish the respectful reader sees the miracle and wonder behind- There are 2 major changes (1st Change) The source of energy The source of energy is the motion energy– No longer the sun mass be used as the sun rays source of energy- BUT – the motion energy is used as the source of energy – here- the fatal error of the sun nuclear fusion theory is seen clearly – because- the solar system is so rich in motion energy- the moving planets since thousands of years provide massive motion energy stored in the space- and by that- the solar system is very rich system in the motion energy- and we should ask (why do we need an outer source of energy?) why the solar system doesn't use its massive motion energy to produce the light beam? Also if the massive motion energy is not used- where's this massive energy? because it can cause continuous risk for the soalr system stability if no way to use this stored massive energy The sun nuclear fusion theory is completely wrong because it doesn't see the massive motion energy stored in the solar system (2nd Change) the light beam production machine The gravitational waves motions can produce the light beam- this is stated by the article but how? by what method the gravitational waves can produce the light beam? The article doesn't explain how the gravitational waves can produce a light beam? But I put an explanation for this method in my theory discussion

2nd Theory (My Theory) I suppose the gravitational waves are produced by the planets motions energies- let's remember my theory because we will use it in the waves properties discussion I asked –where any moving body produce energy by its motion =(1/2 mv^2), where's Planet motion energy? The planet can NOT store its motion energy inside its body because it would raise its temperature and No planet temperature is raised by its motion- logically- the planet motion energy is stored in the space in waves form- means- Planet motion energy creates waves in the space- the planet motion in the space is similar to a fish swimming in the sea- as fish swimming creates waves in the water planet motion energy creates waves in the space- means planet moves and creates waves in space and these waves move by velocity equal this planet velocity by that- for example- Mercury (47.4 km/s) moves in the space and creates waves move by equal velocity (47.4 km/s)- based on this idea- All planets move and their motions create waves move by these planets velocities – AND I suppose these waves are the gravitational waves AND The planets revolve around the sun in the same one direction and for that their motions energies create waves in the space and these waves move perpendicular on the revolution direction (Toward Pluto orbit) AND In Pluto orbit these waves are unified together into one unified wave- this wave moves by a velocity = 205.8 km/s = the planets velocities total

I explained this theory before in more details- now – let's discover the gravitational waves properties and features in details- let's put this analysis in the next point (third point) because we need to analyze the wave reflection process to discover the waves properties and features

Third Point (The Gravitational Waves Reflection)

Let's ask Question No.(1) If the gravitational waves move by velocity 205.8 km/s, how can they move by speed of light? How the velocity 205.8 km/s can be accelerated to be 300000 km/s (speed of light) and where this acceleration is done? Another question can help greatly this discussion Question No.(2) If The Gravitational Waves Move By Speed Of Light (C=300000 Km/S)- How Can These Waves Produce A Light Beam? Let's think how to answer this question- these gravitational waves move by speed of light (C=300000 km/s) but the light beam production needs the value (C^2= squared speed of light)- means- the wave velocity is squared- and how can the wave velocity to be squared? This feature I have discovered in the solar system- the waves are reflected and the reflection causes to square the velocities- means- the gravitational waves are reflected in the solar system- the gravitational waves before the reflection moved by speed of light (C=300000 km/s) and the reflection causes the velocity to be squared- by that- after the reflection the gravitational waves speed is squared and changed from the speed of light (C=300000 km/s) to be (C^2= squared speed of light) and the light beam is created from this value (C^2) Means- the waves reflection is the method by which the speed of light (C=300000 km/s) is changed into (C^2)- that means- without the waves reflection NO light beam can be created. Notice– the waves reflection is proved strongly in the solar system because it causes to reflect the planets data- means- huge amount of planets data proves the waves reflection–we may remember one example – planet velocity is defined by the rule (v1v2=constant) this rule proves the planets velocities are reflected on each other The paper provides hundreds of similar data proves the waves reflection AND The waves reflection causes to square the velocity- this feature is repeated in the solar system frequently – because- the waves are reflected three times in the solar system for that the velocity squaring is a feature repeated with each reflection and by that the planets data provides a strong proof for it- Shortly- The waves reflection causes to square the velocities- now- let's use this feature to know how the unified wave its velocity (205.8 km/s) can move by speed of light (C=300000 km/s)- (Please note this unified wave is the gravitational wave)

The Gravitational Waves Move By Speed Of Light The unified wave (the gravitational wave) moves by 205.8 km/s and it's reflected, the waves reflection causes to square the velocities (205.8 km/s)^2 = 42683 km/s Means the unified wave after the reflection moves by a velocity 42683 km/s BUT If a particle moves by speed (=0.99 C=297000 km/s), this high velocity motion causes to create relativistic effects specially Lorentz length contraction effect with rate 7.1 Means- the distances should be contracted by the rate 7.1 BUT The waves reflection causes to reflect the geometrical effects and by that the rate (7.1) will cause to increase the length in place of the length contraction- means- the distances will be increased with (7.1) as a result for Lorentz length contraction effect The velocity 42683 km/s will be 42683 x 7.1 = 300000 km/s (Speed Of Light) That explains how the gravitational waves move by (205.8 k/s) can move by speed of light (C=300000 km/s) NOTICE No. (1) Please note the important observation Without 7.1 the velocity will be only 42683 km/s (even after the waves reflection) and NOT the speed of light That tells- the light beam production process depends on the previous light beam production process- means- a motion by (99%) of speed of light should be found before the wave reflection occurrence and without this motion with (0.99 C) the gravitational waves can't move by speed of light because we need a source for Lorentz length contraction effect with rate (7.1) That tells the light production process is done in chain process, the new light beam production depends on the old light beam and if this dependency is removed the gravitational waves can NOT move by the speed of light and No light beam can be created in this case NOTICE No. (2) We need to pay more attention for the importance of the motion by the speed of light- because the technique of the machine depends on the waves reflection- means- the waves can increase its velocity only by the reflection process – now the reflection causes to square the velocities- this is very important news why?? Because - If the waves move by speed of light (C=300000 km/s), the waves reflection will produce the value (C^2= squared speed of light) and from this value the light beam can be produced Now – suppose the wave velocity is less than speed of light- suppose the wave moves by speed = (90%) of the speed of light= (270000 km/s) - the waves reflection will square this speed that will produce (0.81 C^2) which is NOT (C^2= squared speed of light) and as a result No Light Beam Can Be Produced (CONT) please read Can The Physics Science Concept Contradict The Nature System? https://gerges2022.livejournal.com/239455.html Gerges Francis Tawdrous +201022532292 Physics Department- Physics & Mathematics Faculty Peoples' Friendship university of Russia – Moscow

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