'back to the future' shot by albert watson in zoom americain no. 46 march/april 1991

The Founders☪️⭕️

By:

Mahmoud al-Jaghmini

A 5-4 tiling of anti-deSitter space with Calabi-Yau manifolds rotating in CP-4

You said: Has the Wolfram Physics Project proven any laws of Fundamental Physics? ChatGPT said: As of now, the Wolfram Physics Project has not yet proven any laws of fundamental physics in the traditional scientific sense — that is, it has not derived known physical laws like the Standard Model or general relativity from its models in a fully rigorous, universally accepted way. However, here is what has been achieved so far:

Framework Creation Stephen Wolfram and his team have developed a formal computational framework based on hypergraph rewriting systems, proposing that space, time, and physics arise from the evolution of discrete structures according to simple rules.

Derivations of Known Features The project has heuristically derived or simulated features that resemble known aspects of physics, such as: • Causal invariance, a property related to relativity. • Emergent spacetime and Lorentz invariance under certain assumptions. • Indications of quantum behavior via multiway systems and branchial space. • A reformulation of Einstein's equations in terms of causal graphs (though not derived from first principles in this model yet).

Mathematical Insights The effort has produced new mathematical ideas in the areas of: • Graph theory and rewriting systems. • Causal structure and foliations. • Category theory and homotopy applied to physics.

Exploratory Status The project is in an exploratory and foundational stage, focusing on mapping how known physics might emerge from extremely low-level computational processes — essentially suggesting a new paradigm, but not yet establishing it in a way that matches or replaces existing physics frameworks.

Summary While the Wolfram Physics Project is a bold attempt to discover a unified computational foundation for physics, it remains speculative and has not yet produced falsifiable predictions or rigorous derivations of existing laws from its core principles. It is more accurate to say it proposes a path toward such a foundation, rather than having proven one. Would you like a visual or technical example of how one of its models relates to relativity or quantum mechanics?

You said: Are Feynman diagrams causal graphs? ChatGPT said: Great question — Feynman diagrams are not causal graphs, although they share some superficial similarities. Here's a breakdown of the differences and relationships between them:

🔹 What Are Feynman Diagrams? • Feynman diagrams are computational tools in quantum field theory (QFT), used to visualize and calculate probability amplitudes for particle interactions. • Each diagram represents a term in a perturbative expansion of a quantum amplitude. • The axes are not spacetime coordinates in a strict sense; the vertical axis is usually time (heuristically), but the diagrams are mainly symbolic. • Vertices represent interaction points, and lines represent particles propagating, not trajectories in spacetime. ➡️ Feynman diagrams are not literal depictions of what happens in spacetime. They help organize terms in quantum field calculations using a mathematical formalism.

🔹 What Are Causal Graphs? • Causal graphs (in the context of the Wolfram Physics Project and elsewhere) are networks where nodes represent events, and directed edges represent causal dependencies between them. • They explicitly encode the causal structure of a physical system: if event A causes or influences event B, there is an arrow from A to B. • In relativity or computational models like the Wolfram Physics Project, causal graphs reflect the actual structure of spacetime or computational history.

🔸 Key Differences Feature Feynman Diagrams Causal Graphs Purpose Mathematical expansion Represent causal structure

in QFT. of events. Temporal Mostly symbolic Encodes actual causal

Meaning relations. Representation Particle interactions Event causality Used in Quantum Field Theory Relativity, Quantum Gravity, Computational Physics

🔹 Are They Related at All? They are not equivalent, but they both express relationships between events or interactions — just in very different frameworks: • In QFT, Feynman diagrams help compute probabilities. • In causal graph models (like in the Wolfram Physics Project), the entire fabric of spacetime and physics arises from the graph's structure. So while both are graphs involving vertices and edges, their meaning and use are fundamentally different. Would you like a diagram comparing the two visually?

You said: Does the Amplituhedron contain all Feynman diagrams? ChatGPT said: Excellent question — and a deep one. The short answer is: The Amplituhedron does not contain all Feynman diagrams — it replaces them in certain theories, offering a radically different way to compute scattering amplitudes without using any Feynman diagrams at all. Let me explain.

🔹 What Is the Amplituhedron? The Amplituhedron is a geometric object discovered by Nima Arkani-Hamed and collaborators around 2013. It encodes the scattering amplitudes of certain particle interactions in a purely geometric way, without reference to: • Spacetime • Quantum fields • Or Feynman diagrams It was first developed for: • Planar N=4\mathcal{N} = 4N=4 supersymmetric Yang–Mills theory in 4D — a highly symmetric (but not realistic) QFT. • Tree-level amplitudes, later extended to loop-level in that theory.

🔸 Relationship to Feynman Diagrams Feature Feynman Diagrams Amplituhedron Approach Perturbative expansion Geometric encoding Input Fields, vertices, propagators Momentum twistors, combinatorics Intermediate Steps Many diagrams with divergences None; computes final amplitude directly Redundancy Huge (many diagrams cancel) Minimal; built to avoid redundancy Containment Diagrams are not inside the amplituhedron The amplituhedron gives results equivalent to the sum of all diagrams

So, rather than containing Feynman diagrams, the Amplituhedron provides an alternative to them, yielding the same final amplitude but without going through the diagrammatic machinery.

🔹 Implication In certain theories (especially planar N=4 supersymmetric Yang–Mills theory in 4D — a highly symmetric (but not realistic) QFT.), the entire Feynman diagrammatic expansion is replaced by computing a volume or combinatorial feature of the amplituhedron. This is deeply tied to hidden symmetries and positivity structures in the amplitudes.

Summary • ❌ The Amplituhedron does not contain all Feynman diagrams. • ✅ It allows you to compute the total amplitude without them, in some very specific quantum field theories. • 🔬 It suggests there may be more fundamental, geometric formulations of physics than quantum fields and Feynman diagrams. Would you like an illustrative visualization of what the amplituhedron looks like and how it encodes amplitudes?

You said: How many kinds of spontaneous quantum events have been observed to occur in a quantum vacuum? ChatGPT said: In quantum field theory, several types of spontaneous quantum events are predicted — and in some cases observed — to occur in the quantum vacuum, due to its inherent fluctuations and instability. These events arise from the uncertainty principle, which allows temporary violations of conservation laws (like energy conservation) within certain limits. Here's a breakdown of the main kinds:

✅ Observed or Indirectly Confirmed Spontaneous Quantum Events

Vacuum Fluctuations • Description: Temporary appearance of particle–antiparticle pairs (like electron–positron pairs) that annihilate each other shortly after.
 • Evidence: Indirect, but foundational to quantum electrodynamics (QED); shows up in: • Lamb shift
 • Casimir effect
 • Anomalous magnetic moment of the electron


Spontaneous Emission • Description: An excited atom can emit a photon spontaneously due to coupling with the quantum vacuum.
 • Evidence: Well-measured in quantum optics; cannot occur in classical EM theory — requires vacuum field.


Hawking Radiation (Theoretical, but Widely Accepted) • Description: Black holes emit particles due to quantum vacuum fluctuations near the event horizon.
 • Evidence: Not yet observed directly, but supported by consistent theoretical work and analog experiments.


Unruh Effect (Theoretical) • Description: An accelerating observer in a vacuum perceives a warm bath of particles (vacuum looks like it contains particles).
 • Evidence: No direct observation due to extreme acceleration required.


Schwinger Effect (Strong-Field Pair Production) • Description: Creation of electron–positron pairs from vacuum in the presence of a very strong electric field.
 • Evidence: Not yet observed in pure form, but being pursued in high-intensity laser experiments (e.g., ELI, SLAC).


❗ Summary: How Many Kinds? There are at least five major categories of spontaneous quantum events associated with the vacuum: # Event Type Observed? 1 Vacuum fluctuations (virtual particles) ✅ Indirect 2 Spontaneous emission ✅ Direct 3 Hawking radiation ❌ Theoretical only 4 Unruh effect ❌ Theoretical only 5 Schwinger effect ❌ Not yet observed

So, to answer directly: Two kinds have been directly observed (vacuum fluctuations via effects like Casimir and Lamb shift, and spontaneous emission), while three more are theoretically predicted and under investigation. Would you like a timeline or visual map of these phenomena and where they stand in terms of experimental support?

You said: Does Quantum Foam exist? ChatGPT said: Quantum foam — also known as spacetime foam — is a hypothetical concept, not yet observed, but widely discussed in theoretical physics as a possible feature of spacetime at the Planck scale (~ 10 − 35 10^{-35} 10 −35 meters). Here's a detailed breakdown of what that means:

🔹 What Is Quantum Foam? • Proposed by John Wheeler in the 1950s. • Describes the idea that at very small scales, spacetime is not smooth, but fluctuates violently due to quantum uncertainty. • Instead of a flat or gently curved spacetime (as in general relativity), quantum foam suggests a chaotic structure where: • Tiny virtual black holes may pop in and out of existence. • Topology and geometry fluctuate, possibly tearing and reconnecting. • Space and time themselves may be emergent phenomena, not fundamental. This is analogous to how a calm ocean surface looks flat from afar, but is foamy and turbulent up close.

🔬 Does It Exist? ❌ No direct experimental evidence • Quantum foam is predicted to occur at the Planck scale, far beyond current experimental resolution. • We can't probe distances smaller than about 10−1910^{-19}10 • −19 • meters even at the LHC, which is 16 orders of magnitude too large to test quantum foam directly. ✅ Strong theoretical motivation • Most approaches to quantum gravity (like loop quantum gravity, string theory, causal dynamical triangulations, and the Wolfram Physics Project) predict some form of non-smooth, fluctuating microstructure of spacetime — very much like quantum foam. • It plays a role in ideas about the holographic principle, black hole entropy, and emergent spacetime. 🧪 Proposed observational hints (not confirmed) • Light dispersion from distant gamma-ray bursts — some models predict tiny energy-dependent delays due to quantum foam. So far, data places upper bounds, but no detection. • LIGO and gravitational wave detectors have been proposed to test Planck-scale noise, but again, no positive results yet.

🧾 Summary Quantum foam has not been directly observed, but it remains a compelling theoretical prediction of many quantum gravity models. You can think of it as a plausible but unconfirmed microscopic structure of spacetime — similar to how atoms were theorized long before they were observed. Would you like to explore which quantum gravity theories describe quantum foam explicitly, or see a visual analogy of how it would distort spacetime?

You said: In the Wolfram Physics model, would the Quantum Foam accomplish Computation? ChatGPT said: Yes — in the Wolfram Physics Project, the analog of quantum foam is not just a fluctuating structure but is fundamentally computational in nature. In fact, computation is what drives everything in the model.

🔹 The Core Idea In Wolfram's model, the universe is represented by the evolution of a hypergraph, where: • Nodes represent abstract "atoms of space". • Edges represent relationships between those nodes. • A set of simple rewriting rules updates this graph over time. This process is computational, and the universe is essentially a giant distributed computation.

🔸 So, Is There Quantum Foam? Yes — though not called that formally, the fine-grained structure of the hypergraph at very small scales behaves like a quantum foam, because: 1. The graph is discrete and locally fluctuating. 2. The structure changes in a non-deterministic way due to multiway branching — capturing quantum indeterminacy. 3. The causal graph formed by applying update rules encodes both quantum mechanics and general relativity in a unified computational framework. 4. The universe does not evolve linearly; it evolves through all possible paths consistent with the rules — similar to a Feynman path integral or quantum superposition.

🔹 Computation in the "Foam" In this model: • The quantum-foam-like structure is not passive; it actively computes all possible evolutions. • This is what gives rise to: • Causal relationships • Quantum interference • Entanglement • Space, time, particles, and forces • Observers are just specific computational processes embedded in this system. Wolfram refers to this as "the ruliad" — the limit of all possible computations following all possible rules. The foam is essentially a slice of the ruliad, constrained by the rules we experience.

🧾 Summary In the Wolfram Physics Project, the quantum-foam-like structure of space is inherently computational — it both encodes and performs the fundamental computation that produces the universe. Would you like a visual simulation of how a simple hypergraph evolves in this model, to see how spacetime and causality emerge?

You said: Given Max Tegmark: "If Consciousness is how information feels as it is being processed, then Consciousness is doubly substrate-independent." Does this imply that the Quantum Foam may support some degree of Consciousness? ChatGPT said: That's a profound and nuanced question — and one that treads the boundary between physics, information theory, and philosophy of mind. Let's unpack it carefully.

🔹 Max Tegmark's View: Consciousness as Information Processing Max Tegmark's quote suggests the following key ideas: 1. Consciousness is the subjective experience of information processing. 2. Information processing is substrate-independent, meaning it can, in principle, happen on any medium — silicon, neurons, paper, or something more exotic. 3. Therefore, consciousness is also substrate-independent, if it's tied strictly to the structure and flow of information. This idea is central to what Tegmark calls the "Mathematical Universe Hypothesis" and his related work on consciousness (e.g., "Perceptronium" — the idea that consciousness is a state of matter defined by specific information-processing properties).

🔸 Does This Apply to Quantum Foam or the Wolfram Model? Now let’s connect this with the quantum foam and Wolfram’s physics model: 🔸 1. Is the quantum foam computational? • In standard quantum field theory or general relativity, quantum foam is a hypothesized physical fluctuation at Planck scales — it's not defined in terms of information or computation. • In Wolfram’s model, however, the fine structure of spacetime is explicitly a computational substrate — a hypergraph updated by rules. That is information processing. 🔸 2. Could it support consciousness? • If consciousness = certain types of information processing, and if quantum foam (or the hypergraph in Wolfram’s model) supports rich and self-referential computation… • Then yes, in principle, such a system could support consciousness, at least in a substrate-independent sense. But that hinges on a few assumptions: • Consciousness is only information processing (functionalism). • No special "biological" or "material" features are needed (non-biological pancomputationalism). • The quantum foam or hypergraph can reach the complexity, integration, and feedback needed (like in Tononi's Integrated Information Theory or other cognitive models).

🧠 Key Insight If the structure underlying reality — such as quantum foam or the hypergraph of Wolfram's model — is capable of implementing sufficiently rich and integrated computation, and if consciousness arises from such computation, then yes, consciousness could, in principle, emerge or be supported by that structure. This does not imply that the quantum foam is conscious per se — but rather that it might be able to support conscious processes, just as neurons or silicon circuits do.

🧾 Summary • Tegmark’s quote suggests consciousness is an emergent property of computation. • Quantum foam in standard physics is not inherently computational, so the implication is weak there. • Wolfram's hypergraph-based quantum foam, however, is computational, and thus, could in principle support consciousness, if it meets the required complexity and dynamics. Would you like to explore what specific kinds of information processing might be necessary for consciousness to emerge from a computational substrate like this?

"The Unified Field of Quantum Physics is the same as the Unified Field of Pure Consciousness." John Hagelin, Ph.D, Raja of Invincible America

Safe travels, old man. Thank you, thank you, thank you.

The day after David Lynch died, Portland-based writer Katherine Cusumano drove up to Washington. It was a journalistic impulse, but also a deeply personal one. In a dispatch from the real Twin Peaks, Cusumano writes about art, Lynch’s connection to the Northwest, and collective mourning. She asks: In times of grief, what do we get from stepping into places depicted in art?

I wondered if the instinct to go to a place that a beloved artist touched was a way of restoring a trajectory. Situating yourself literally inside an artist’s work could be read as another way of metabolizing influence.

Read this week’s new essay, “David Lynch Was Here,” on Longreads.

Photography by Riley Yuan.

The Sky Map of Ancient Nineveh, 3300 B.C.

The origins of Western astronomy can be found in Mesopotamia, and all Western efforts in the exact sciences are descendants in direct line from the work of the late Babylonian astronomers. This circular cuneiform tablet is a reproduction after a Sumerian star map, which perfectly matches the sky above Mesopotamia, in 3300 B.C.

It is an astrolabe, one of the oldest tools used for locating and predicting the positions of the Sun, Moon, planets, and stars. Some call this the Sodom and Gomorrah Tablet because it describes a comet/asteroid which some think destroyed Sodoma and Gomorrah around 3300 B.C.

Devotional AI

h/t Kevin Geiger on facebook

h/t WIDOMIRAMA on Flickr

A 5-4 tiling of anti-deSitter space with Calabi-Yau manifolds rotating in CP-4