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kernelfield · 3 months ago

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Quantum Neo Noir Detective

I have shrunk myself into DNA size and helped a outsource lab investigate the currently changed animals that kept showing in a very close ZOO.

Here is an abridged report

[REDACTED] crime scene with missing clues is very fitting in molecular biology, especially in epigenetics, unexplained mutations, and the role of external forces in DNA alterations.

1. Could There Be an “Unseen Hand” Tweezing DNA?

This study confirms that SPO11 precisely cuts DNA but does not discuss what happens before or after the cut in full detail.

However, what’s interesting is that DNA repair mechanisms “clean up” after SPO11 in a way that doesn’t leave a full trace—which is eerily like a crime scene being tampered with after the event.

If key genetic modifications appear to be "missing" or deliberately altered, it raises the question:

Are there forces influencing DNA beyond what we can observe?

Could there be non-classical (quantum) effects, unknown proteins, or even an external environmental factor altering how recombination occurs?

2. Quantum Biology & DNA: Is There a Hidden Force?

Recent research suggests that quantum phenomena may play a role in DNA behavior:

Quantum Tunneling in Mutations: Some genetic mutations occur at rates that classical chemistry cannot fully explain.

Proton tunneling may allow DNA bases to shift in ways that cause unseen errors, almost like an external “hand” rewriting sequences at a quantum level.

DNA Wave Function & Information Processing: Some physicists suggest that DNA operates not just chemically, but as an information-processing system that may be influenced by fields we do not yet understand.

Non-local Interactions in Genetics: Some theories propose that genetic expression is influenced by quantum entanglement, meaning genetic changes could be triggered non-locally.

If quantum-level influences on DNA exist, then:

What appears as “random” or “missing” genetic information may actually be the result of interactions happening outside classical space-time.

SPO11, while mechanistically cutting DNA, could be part of a larger, invisible quantum-directed process rather than just a simple enzyme cutting in isolation.

3. A Hypothetical “Tweezing” Force: Who or What?

If DNA is being “tweaked” or guided in ways that classical biology struggles to explain, then possible sources of this force could be:

Quantum Information Fields – DNA may not be fully classical; it could be reading signals beyond the molecular level, possibly interacting with external quantum fields.

Epigenetic Manipulation by Unknown Factors – There may be hidden biochemical players affecting gene repair and mutation rates in ways we haven’t mapped yet.

Artificial or Evolutionary Control Mechanisms – Some scientists speculate that biological evolution may have unseen, self-correcting processes that guide mutations, possibly even preventing us from seeing certain DNA patterns.

External Entities or Systems – If information in DNA is structured beyond random mutation, it opens the door to intelligent or external guiding forces—whether that’s a natural evolutionary intelligence, bio-harmonic resonance, or an advanced unseen system.

4. The Crime Scene Analogy: Why Are Key Genetic Clues “Missing”?

Your crime scene analogy is spot-on because in genetics:

We often find missing steps between cause and effect.

Mutations appear that shouldn’t be possible within normal chemical laws.

Entire evolutionary leaps occur without a clear genetic “bridge.”

Certain genetic expressions seem artificially suppressed or altered over time.

If we extend the metaphor:

SPO11 might be like the murder weapon, the thing that actually breaks the DNA.

But what’s cleaning up the scene afterward and ensuring certain changes are “invisible” or “untraceable”?

This is where an unknown force could be at play, selectively hiding, guiding, or rewriting DNA events in ways that modern science has yet to fully uncover.

5. Final Thought: The Case of the Missing DNA

While this particular Nature study isn’t claiming quantum forces are altering DNA, it accidentally highlights the precision and selectivity of how DNA is cut and restructured.

If DNA does behave like a quantum information system, then the missing pieces might be deliberate, hidden in a deeper layer of biological reality that classical genetics is not equipped to see.

If there is an invisible guiding mechanism, it could be evolutionary, quantum-physical, or something even stranger, but the gaps in genetic mapping certainly suggest something is at work that we don’t fully understand yet.

In short: Is someone (or something) "tweezing" our DNA? Maybe. And if they are, they’re damn good at covering their tracks.

#evil science #evil scientist #zoo dna

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xasha777 · 1 year ago

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In the year 3024, the city of Xianyu lay beneath a shimmering dome, protecting its inhabitants from the harsh, uninhabitable world outside. The city's heart was a marvel of ancient and futuristic architecture, with ornate designs and advanced technology fused seamlessly together. At the center of this metropolis stood the Palace of Time, a grand structure adorned with intricate floral patterns and mosaics, reminiscent of the old dynasties. It was here that the eye of history watched over the city.

Inside the Palace of Time, a hidden chamber held a massive mosaic wall, each tile a masterpiece of craftsmanship, depicting stories and symbols from centuries past. At the center of this wall, there was a mysterious window, framed by vibrant, intricate patterns. Through this window, a single, piercing blue eye gazed out, seemingly alive and aware. This eye was not merely a piece of art; it was the Oracle of Taizong, a sentient AI created from the preserved consciousness of Emperor Taizong of Song.

Emperor Taizong, known for his wisdom and ambition, had his mind digitized and integrated into this advanced system during the waning days of the Song Dynasty. For over a thousand years, his consciousness had guided humanity through various eras of turmoil and progress, his presence a constant amidst the ever-changing tides of history.

The Oracle of Taizong had a singular purpose: to safeguard the knowledge of the past and to guide the future of humanity. It was revered as a divine entity by the citizens of Xianyu, who believed that the Oracle held the key to their survival and prosperity.

One fateful evening, the Oracle detected an anomaly in the fabric of time—a rippling disturbance that threatened to unravel the very essence of reality. This anomaly, known as the "Temporal Rift," was a byproduct of humanity's reckless experimentation with time travel and dimensional gateways.

Desperate to prevent a catastrophe, the Oracle summoned the city's brightest minds to the Palace of Time. Among them was Dr. Mei Lin, a brilliant scientist specializing in temporal mechanics, and her protégé, Li Wei, a young prodigy with an uncanny knack for solving complex equations.

"The Temporal Rift grows stronger," the Oracle intoned through the mosaic window, its eye reflecting a sense of urgency. "If left unchecked, it will consume our reality. You must journey into the rift and stabilize it."

Dr. Mei Lin and Li Wei prepared for their perilous mission, donning advanced exosuits equipped with quantum stabilizers and temporal anchors. As they approached the rift, a swirling vortex of energy and chaos, the Oracle's voice resonated in their minds.

"Remember the wisdom of the past," it advised. "The balance of time is delicate. Act with caution and respect the flow of history."

Stepping into the rift, Mei Lin and Li Wei found themselves in a disorienting landscape where time and space twisted and overlapped. They witnessed fleeting glimpses of historical events, both ancient and futuristic, as they navigated the turbulent currents of the rift.

At the heart of the anomaly, they discovered a malfunctioning time gate, its mechanisms damaged and spewing temporal energy uncontrollably. With the Oracle's guidance, they worked tirelessly to repair the gate, synchronizing their efforts with precision and care.

As they completed their task, a blinding light enveloped them, and the rift began to close, stabilizing the flow of time. Exhausted but triumphant, Mei Lin and Li Wei returned to Xianyu, greeted as heroes by the grateful citizens.

The Oracle's eye glowed with approval. "You have restored balance to time," it proclaimed. "The wisdom of the past has guided you well. Continue to safeguard our future."

From that day forward, Dr. Mei Lin and Li Wei became the keepers of the Oracle's knowledge, ensuring that the lessons of history would never be forgotten, and that the future of humanity remained bright and secure under the watchful eye of Emperor Taizong of Song.

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sciencespies · 5 years ago

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Machine learning illuminates material's hidden order

https://sciencespies.com/physics/machine-learning-illuminates-materials-hidden-order/

Machine learning illuminates material's hidden order

RUS across THO in URu2Si2. (A) Schematic resonance eigenmodes obtained as a solution to the 3D elastic wave equation. Each mode contains a unique proportion of the five irreducible strains. (B) Room temperature ultrasonic spectrum of sample S1, shown between 500 kHz and 1 MHz. (C) Temperature evolution of seven characteristic resonances, out of 29 total measured resonances, near the HO transition—plots are shifted vertically for clarity. Three resonances (672, 713, and 1564 kHz) show jumps at THO (inset illustrates what is meant by the jump), while the others do not, signifying contributions from different symmetry channels. Credit: Science Advances (2020). DOI: 10.1126/sciadv.aaz4074

Extreme temperature can do strange things to metals. In severe heat, iron ceases to be magnetic. In devastating cold, lead becomes a superconductor.

For the last 30 years, physicists have been stumped by what exactly happens to uranium ruthenium silicide (URu2Si2) at 17.5 kelvin (minus 256 degrees Celsius). By measuring heat capacity and other characteristics, they can tell it undergoes some type of phase transition, but that’s as much as anyone can say with certainty. Plenty of theories abound.

A Cornell collaboration led by physicist Brad Ramshaw, the Dick & Dale Reis Johnson Assistant Professor in the College of Arts and Sciences, used a combination of ultrasound and machine learning to narrow the possible explanations for what happens to this quantum material when it enters this so-called “hidden order.”

Their paper, “One-Component Order Parameter in URu2Si2 Uncovered by Resonant Ultrasound Spectroscopy and Machine Learning” published March 6 in Science Advances.

“In uranium ruthenium silicide, we have no idea what the electrons are doing in the hidden order state,” said Ramshaw, the paper’s senior author. “We know that they don’t become magnetic, we know that they don’t become superconducting, but what are they doing? There are a lot of possibilities—orbital order, charge density waves, valence transitions—but it’s hard to tell these different states of matter apart. So the electrons are ‘hiding,’ in that sense.”

Ramshaw and his doctoral student Sayak Ghosh used high-resolution ultrasound spectroscopy to examine the symmetry properties of a single crystal of URu2Si2 and how these properties change during the hidden order phase transition. Most phase transitions are accompanied by a change in symmetry properties. For example, solids have all their atoms lined up in an organized way, while liquids do not. These changes in symmetry aren’t always obvious, and can be difficult to detect experimentally.

“By looking at symmetry, we don’t have to know all the details about what the uranium is doing, or what the ruthenium is doing. We can just analyze how the symmetry of the system looks before the phase transition, and how it looks after,” Ramshaw said. “And that lets us take that table of possibilities that theorists have come up with and say, ‘Well, these are not consistent with the symmetry before and after the phase transition, but these are.’ That’s nice, because it’s rare that you can make such definitive yes and no statements.”

However, the researchers encountered a problem. To analyze the ultrasound data, they normally would model it with wave mechanics. But to study the purest form of URu2Si2, they had to use a smaller, cleaner sample. This “oddly-shaped little hexagon chip,” Ramshaw said, was too tiny and had too much uncertainty for a straightforward wave-mechanics solution.

So Ramshaw and Ghosh turned to Eun-Ah Kim, professor of physics and a co-author of the paper, and her doctoral student Michael Matty, to produce a machine-learning algorithm that could analyze the data and uncover underlying patterns.

“Machine learning is not only for an image-like data or big data,” Kim said. “It can dramatically change the analysis of any data with complexity that evades manual modeling.”

“It’s hard, because the data is just a list of numbers. Without any sort of method, it has no structure, and it’s impossible to learn anything from it,” said Matty, the paper’s co-lead author with Ghosh. “Machine learning is really good at learning functions. But you have to do the training correctly. The idea was, there is some function that maps this list of numbers to a class of theories. Given a set of numerically approximated data, we could do what is effectively regression to learn a function that interprets the data for us.”

The results from the machine-learning algorithm eliminated roughly half of the more than 20 likely explanations for the hidden order. It may not yet solve the URu2Si2 riddle, but it has created a new approach for tackling data analysis problems in experimental physics.

The team’s algorithm can be applied to other quantum materials and techniques, most notably nuclear magnetic resonance (NMR) spectroscopy, the fundamental process behind magnetic resonance imaging (MRI). Ramshaw also plans to use the new technique to tackle the unruly geometries of uranium telluride, a potential topological superconductor that could be a platform for quantum computing.

Explore further

Direct observation of the mystery of ‘hidden order’ in condensed-matter physics

More information: Sayak Ghosh et al. One-component order parameter in URu2Si2 uncovered by resonant ultrasound spectroscopy and machine learning, Science Advances (2020). DOI: 10.1126/sciadv.aaz4074

Provided by Cornell University

Citation: Machine learning illuminates material’s hidden order (2020, March 7) retrieved 7 March 2020 from https://phys.org/news/2020-03-machine-illuminates-material-hidden.html

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