GSC Model: Derivations from First Principles

A collaborative workspace for deriving new physical insights from the Ground State Configuration (GSC) model through emergent gravity and informational dynamics.

1. Black Hole Phenomena

Black holes represent the ultimate laboratory for any theory of quantum gravity. The GSC model's core tenets—that information is fundamental and spacetime is emergent—should provide a powerful framework for resolving long-standing paradoxes.

1.1. The Information Paradox

The GSC Model Approach: In the GSC model, information is never destroyed. It undergoes a transformation from being locally accessible to being encoded in the non-local correlational structure of the multiverse. This happens via a continuous process of causal history imprinting during infall.

Proposed Derivation Steps:

Modeling the State in the GSC Hilbert Space:
The full Hilbert space is a tensor product of the local branch and the multiverse: $\mathcal{H}_{GSC} = \mathcal{H}_{local} \otimes \mathcal{H}_{multi}$. An infalling electron begins in a state largely unentangled with the multiverse:

$$|\psi_{e}\rangle_{initial} = |\psi_{local}\rangle \otimes |\psi_{multi}^{0}\rangle$$
Continuous Information Transfer via Relativistic Branching:
As the electron falls, it continues to interact with the local quantum vacuum. This interaction, governed by an interaction Hamiltonian $H_{int}(t)$, causes a continuous branching of its causal history into the multiverse. This is not a single event, but a gradual process where the electron's state evolves unitarily:

$$|\Psi(t)\rangle = \mathcal{T} e^{-i \int_{t_0}^{t_f} H_{int}(t') dt'} |\Psi(t_0)\rangle$$

The operator $\mathcal{T} e^{-i \int H_{int}(t') dt'}$ represents the time-ordered evolution that progressively entangles the local state with $\mathcal{H}_{multi}$.
Conservation of Informational Freedom during Infall:
The total information, $S_{total}$, is conserved. As the electron falls, its ability to be in a superposition of states locally diminishes ($S_{local} \to 0$). This loss of local freedom is precisely compensated by an increase in its entanglement with the multiverse ($S_{multi}$ increases), as its causal history is imprinted across many branches.

$$\frac{dS_{local}}{dt} = -\frac{dS_{multi}}{dt}$$

The process concludes when no "superpositional invariance" remains—the particle has fully decohered with the local system and its information is now entirely non-local.
Hawking Radiation and the Concept of Multiversal Time:
The imprinted causal history is not static. The parameter tracking the evolution of this branching and entanglement can be understood as a form of "multiversal time." Hawking radiation is the mechanism by which this process runs in reverse: quantum fluctuations at the horizon couple to the imprinted history, slowly untangling it and leaking the information back into $\mathcal{H}_{local}$ as correlated radiation.
Deriving the Page Curve:
The Page Curve emerges naturally from this model. The "turn" of the curve happens at the Page time—the point where the rate of information being returned to our universe via Hawking radiation (the untangling of causal histories) becomes greater than the rate of information being imprinted by new infalling matter. The entropy of the radiation $S(\rho_{rad})$ must then decrease, ensuring the total process is unitary.

$$S(\rho_{rad}) = -\text{Tr}(\rho_{rad} \log \rho_{rad})$$

1.2. Decomposing Black Hole Mass: Local vs. Multiversal Components

Problem Statement: An observer at infinity measures the total mass-energy of a black hole ($M_{ADM}$). In the GSC model, this mass should have two distinct origins: (1) the mass-energy of local matter currently undergoing informational transfer, and (2) the effective mass-energy of information already encoded into the multiverse structure, which is felt gravitationally as an entropic force.

The GSC Model Approach: We can decompose the total mass into a local component ($M_{local}$) and a multiversal component ($M_{multi}$) by relating mass directly to the informational entropy of the system.

Proposed Derivation Steps:

The Mass-Information Equivalence Postulate:
We postulate that mass-energy is a manifestation of information. The total mass $M$ of a system is proportional to its total informational content (entropy) $S$. Let $\alpha$ be a fundamental constant linking information to mass, with units of mass/entropy.

$$M = \alpha S$$
Decomposition of Mass:
The total mass of the black hole, $M_{total}$, can be decomposed into two parts based on the state of the information within it:
- $M_{local}$: The mass from information that is still local and has not been fully imprinted into the multiverse. This is proportional to $S_{local}$.
- $M_{multi}$: The effective mass from information that is fully encoded in the multiverse entanglement structure. This is proportional to $S_{multi}$.
The total mass is the sum of these components:

$$M_{total} = M_{local} + M_{multi} = \alpha S_{local} + \alpha S_{multi}$$
Evolution of Mass Components:
The evolution of the black hole's mass composition can now be described. For a **young, accreting black hole**, it is actively consuming local matter, so $S_{local}$ is large, and $M_{local}$ is a significant fraction of the total mass. For an **old, isolated black hole**, most of its initial information has been fully imprinted. Therefore, $S_{local} \to 0$ and its mass is almost entirely multiversal: $M_{total} \approx M_{multi}$.
Testable Prediction:
This decomposition could have observational consequences. The gravity generated by $M_{local}$ should behave like standard stress-energy, while the gravity from $M_{multi}$ is an entropic force. This could lead to subtle deviations from General Relativity in the spacetime near a black hole, depending on its age and accretion history. These deviations might be detectable in the gravitational wave signals from binary black hole mergers, particularly in the ringdown phase.

2. Cosmological Puzzles

Here we will explore the GSC model's potential to explain the origin and evolution of the universe.

2.1. Cosmic Inflation without an Inflaton

Problem Statement: Explain the rapid, exponential expansion of the early universe, which is required to solve the horizon and flatness problems, without postulating a new fundamental scalar field (the inflaton).

GSC Approach: Inflation was not driven by a field, but by an informational phase transition. The early universe was in a highly ordered, simple, low-entropy state (a "false vacuum"). Inflation was the thermodynamic process of this state rapidly evolving towards a higher-entropy, more complex configuration, releasing enormous energy that drove spacetime expansion.

Proposed Derivation Steps:

The Pre-Inflationary State:
Model the initial state of the GSC as a highly symmetric, low-complexity graph. This state has a very low informational entropy, $S_{initial} \approx 0$. This corresponds to a "false vacuum" with a high potential energy density, $\rho_{vac}$.
The Phase Transition Trigger:
This false vacuum is metastable. A quantum fluctuation (a random "re-wiring" of the GSC graph) triggers a phase transition. The system begins to rapidly explore more complex, higher-entropy configurations. This is an irreversible thermodynamic process.
The Equation of State for the Transition:
The key is to derive the effective equation of state for this informational fluid. The energy released from the transition creates a negative pressure. As the GSC network rapidly increases its complexity and entropy, it creates an outward informational pressure, $P$. We must show this pressure is related to the vacuum energy density $\rho_{vac}$ by:

$$P \approx -\rho_{vac}$$

This equation of state is the mathematical requirement for exponential expansion (inflation) when plugged into the Friedmann equations.
The "Graceful Exit":
The inflationary phase ends when the GSC network reaches a new, stable, higher-entropy ground state (the "true vacuum"). The energy that was driving inflation is converted into the hot plasma of particles and radiation of the Big Bang. This process, known as "reheating," happens naturally as the network settles and its excess energy is thermalized into local excitations (particles).
Deriving Primordial Fluctuations:
The seeds of galaxies and large-scale structure are quantum fluctuations from the inflationary era. In the GSC model, these are not fluctuations of an inflaton field, but are residual quantum uncertainties in the final structure of the GSC graph after the phase transition. We should be able to calculate the power spectrum of these informational fluctuations and show that it is nearly scale-invariant, matching observations from the Cosmic Microwave Background.

2.2. Baryon Asymmetry

Problem: Explain the observed dominance of matter over antimatter.
GSC Approach: Investigate asymmetries in the GSC's fundamental "computational rules."
[Start derivation here...]

3. Quantum Foundations

This section will focus on deriving the foundational principles of quantum mechanics itself from the GSC model.

3.1. The Measurement Problem & The Born Rule

Problem Statement: Why does a quantum system in a superposition of states $|\psi\rangle = \sum c_i |i\rangle$ appear to "collapse" to a single outcome $|k\rangle$ upon measurement, and why is the probability of this outcome given by the Born Rule, $P(k) = |c_k|^2$?

GSC Approach: Measurement is not a collapse. It is a unitary process of entanglement between a quantum system and a macroscopic apparatus. The apparent collapse is a consequence of decoherence, and the probabilities arise from the observer's self-location within the resulting multiverse branches.

Proposed Derivation Steps:

System Setup:
Consider a simple quantum system (a qubit) in a superposition: $|\psi\rangle_S = c_0|0\rangle_S + c_1|1\rangle_S$. The measuring apparatus (and its environment, including the observer) is a complex system initially in a ready state $|A_0\rangle$. The total initial state is unentangled:

$$|\Psi\rangle_{initial} = (c_0|0\rangle_S + c_1|1\rangle_S) \otimes |A_0\rangle$$
Unitary Interaction and Entanglement:
The measurement is a physical interaction described by a unitary operator $U_{measure}$. This interaction couples the state of the system to the state of the apparatus. For example, if the system is $|0\rangle$, the apparatus pointer goes to "0"; if the system is $|1\rangle$, the pointer goes to "1".

$$U_{measure}(|0\rangle_S \otimes |A_0\rangle) = |0\rangle_S \otimes |A_{0p}\rangle$$ $$U_{measure}(|1\rangle_S \otimes |A_0\rangle) = |1\rangle_S \otimes |A_{1p}\rangle$$

Applying this to the superposition gives a final, entangled state:

$$|\Psi\rangle_{final} = c_0(|0\rangle_S \otimes |A_{0p}\rangle) + c_1(|1\rangle_S \otimes |A_{1p}\rangle)$$
Decoherence and Branching:
The apparatus states $|A_{0p}\rangle$ and $|A_{1p}\rangle$ are macroscopic and immediately decohere with the environment (the rest of the GSC multiverse). They become orthogonal very quickly: $\langle A_{0p} | A_{1p} \rangle \approx 0$. The final state now describes two effectively separate, non-interacting branches of the multiverse. There is no collapse; the entire superposition still exists, but its components are causally disconnected.
Observer Self-Location and Probability:
An observer is part of the apparatus/environment. To have a conscious experience, the observer's state must also be in one of the branches. The question "What is the probability of seeing outcome '0'?" becomes "In what fraction of worlds does a copy of me see the outcome '0'?". We need a way to measure the "size" or "weight" of each branch.
Deriving the Measure: The Born Rule:
We postulate that the only rational, consistent measure for the weight of a branch is the squared magnitude of its amplitude. Why? Consider the symmetries of the state. The overall phase of $|\Psi\rangle_{final}$ is unphysical. Furthermore, the relative phases between the $c_0$ and $c_1$ terms are unobservable after decoherence. Any valid probability measure $P(c_i)$ must be independent of these phases. The simplest function that satisfies this is $P(c_i) = |c_i|^2$. This principle, known as envariance (entanglement-assisted invariance), suggests that the squared amplitude is the natural choice. Therefore, the probability of an observer finding themselves in the "0" branch is:

$$P(0) = \frac{|c_0|^2}{|c_0|^2 + |c_1|^2} = |c_0|^2$$

(Assuming the state is normalized, $|c_0|^2 + |c_1|^2 = 1$). This derives the Born rule not as a separate axiom, but as a consequence of unitary evolution and the nature of observation within the GSC's multiverse structure.