The De Giuseppe Multi-Sheet Topological Qubit: Emergent Quantum Computation from Space-Time Geometry

Abstract

We introduce the De Giuseppe Qubit (DGQ), a novel quantum computational unit that leverages multi-sheet topological structures of space-time predicted by the Topological Phase Signalling Theorem (TPST). Unlike conventional qubits confined to a single space-time sheet, the DGQ exists simultaneously across multiple topologically connected sheets, providing emergent entanglement, intrinsic decoherence suppression, and super-parallel computation. This framework formalizes multi-sheet Hilbert spaces, sheet-symmetric operators, Hamiltonian dynamics, energy-momentum coupling, and holographic regularization of entanglement divergences. We present key equations underpinning the DGQ, demonstrating how computation can emerge from the geometry of space-time itself.

Please note:

This record is the hub of my theory (TPST-DQG)

( I also added the other my articles:

"Holographic Extension as a Dynamic Mechanics for Bulk Geometry CTC with Topological Phase Signalling Theorem"

And

"Worldline Non-Injectivity as a Necessary and Sufficient Condition for the Emergence of Holographic Spacetime"

And

"Quantum Mechanics as Topological Intersection Theory: The Born Rule, Wavefunction Collapse, and Planck's Constant from Worldline Non-Injectivity"

And my other works

to help better understand the multisheet DGQ paper.

I hope it is appreciated.)

Attention, Important :

"paradox 20_2026-04-07_184929.pdf" (Worldline Non-Injectivity as a Necessary and Sufficient
Condition for the Emergence of Holographic Spacetime}

and

 
"paradox 10.0-18.0_2026-04-07_151539.pdf" ( Holographic Extension of the Topological Phase Signalling Theorem: Entanglement-Induced Bulk Geometry Dynamics (Detailed Version))

are the two fundamental papers that allow for an understanding of all the others present in the record.

Other works in this record:

"paradox 10.0-18.0_2026-04-06_115105.pdf"
as "Lorentz Transformations beyond Injectivity: The Ziegelstein Gedankenexperiment and the Emergence of Multi-Sheet Spacetime: From the Bricks Paradox to Multi-Sheet Spacetime Structure"

"paradox 20_2026-04-09_144031.pdf"
as "Quantum Mechanics as Topological Intersection Theory: The Born Rule, Wavefunction Collapse, and Planck's Constant from Worldline Non-Injectivity"

"paradox 20_2026-04-11_030415.pdf" as
"Electromagnetic Fields in Multi-Sheet Spacetime: Sheet-Dependent Field Ratios, Charge Quantisation, and a New Experimental Prediction from Extended Lorentz Transformations"

"paradox 10.0-18.0_2026-04-15_204938.pdf"
as "Tidal Forces, the Equivalence Principle, and the Emergence of the Einstein Field Equations from Worldline Non-Injectivity in de~Sitter Spacetime"

"paradox 20_2026-04-08_104825 (1).pdf"
as "Mirror Reflection in Multi-Sheet Spacetime: Anticipatory Images from Extended Lorentz Transformations and Worldline Non-Injectivity"

"paradox 10.0-18.0_2026-04-09_214121.pdf"
as "Topological Entropy: A New Principle from Worldline Non-Injectivity"

"paradox 10.0-18.0_2026-04-16_135616 (1).pdf"
as "The Pauli Exclusion Principle and the Spin-Statistics Theorem from Worldline Non-Injectivity: Exchange Phase, Rapidity, and Topological Sheet Structure"

"paradox 10.0-18.0_2026-04-18_174928 (2).pdf"
as "Noncommutative Spacetime and the Generalised Uncertainty Principle from Worldline Non-Injectivity: A Geometric Derivation of -Minkowski and the GUP"

"paradox 10.0-18.0_2026-04-26_001823.pdf" as "Poincarè Symmetries, Gravitoelectromagnetic Coupling, and Emergent Conservation Laws from Worldline Non-Injectivity"

1. Introduction

Quantum computation traditionally relies on coherent manipulation of qubits, often represented as
[
|\psi\rangle = \alpha |0\rangle + \beta |1\rangle, \quad \alpha, \beta \in \mathbb{C}, \quad |\alpha|^2 + |\beta|^2 = 1.
]
Topological qubits improve resilience to decoherence by encoding information in non-local degrees of freedom, but still require explicit entangling operations. The DGQ generalizes this approach: a single qubit is embedded across N topologically connected sheets, generating intrinsic entanglement and enabling parallel computation without conventional gates.

This document introduces the DGQ framework, including:

1. Multi-sheet Hilbert space formalism and operators;

2. Hamiltonian dynamics with topological correlations;

3. Observer-state gravitational coupling and emergent cosmological constant;

4. Master TPST equation unifying bulk entanglement and geometry;

5. Holographic regularization and decoherence suppression.

2. Topological Phase Signalling Theorem (TPST)

The DGQ relies fundamentally on TPST, which formalizes how state-dependent global unitaries induce correlated changes across subsystems without explicit entangling gates.

Consider a tripartite system:
[
\mathcal{H} = \mathcal{H}_A \otimes \mathcal{H}_B \otimes \mathcal{H}_F,
]
with $A$ the control subsystem, $B$ the target, and $F$ an auxiliary system. A state-dependent global unitary is defined as
[
U(\rho) = \exp\big(-i \phi[\rho] \hat{G}\big),
]
where $\hat{G}$ acts nontrivially on $BF$, and $\phi[\rho]$ depends on the global state. TPST states that distinct operations on $A$ induce distinct reduced states on $B$:
[
\rho_B^{(V)} \neq \rho_B^{(V')}, \quad \text{for suitable } V_A \neq V'_A.
]

Constructive Example

For qubits ($\mathbb{C}^2$) with Pauli operators $\hat{X},\hat{Y},\hat{Z}$:
[
\phi[\rho] = g, \mathrm{Tr}[\hat{X}_A \rho], \quad \hat{G} = \hat{Z}_B \otimes \hat{X}_F, \quad \rho_0 = |0\rangle\langle 0|_A \otimes |+\rangle\langle +|_B \otimes |0\rangle\langle 0|_F,
]
and local operations $V_A = \mathbb{I}$, $V'_A = H$ (Hadamard). Then:
[
\rho_B^{(V)} = |+\rangle\langle +|_B, \quad
\rho_B^{(V')} = \frac{1}{2}(\mathbb{I}_B + \cos(2g) \hat{X}_B),
]
demonstrating emergent correlation without direct entangling gates.

3. Multi-Sheet DGQ Formalism

Let each sheet $i=1,\dots,N$ have Hilbert space $\mathcal{H}i$. Define the global DG Hilbert space:
[
\mathcal{H}\text{DG} := \bigotimes_{i=1}^N \mathcal{H}_i.
]

Sheet-Symmetric Operators

[
\hat{\Sigma}\alpha := \frac{1}{N} \sum{i=1}^{N} \sigma_\alpha^{(i)}, \quad \alpha \in {x,y,z}.
]
Eigenstates of $\hat{\Sigma}_\alpha$ encode emergent entanglement, enforcing synchronized evolution across sheets.

Intrinsic Entanglement

For $N=2$:
[
|\Psi_\text{DG}\rangle = \frac{1}{\sqrt{2}}\big(|0\rangle_1 |0\rangle_2 + |1\rangle_1 |1\rangle_2\big),
]
without explicit gates.

4. Hamiltonian Dynamics

Global Hamiltonian:
[
H_\text{DG} = \sum_{i=1}^{N} H^{(i)}, \quad H^{(i)} = H^{(j)} \ \forall i,j.
]

Time evolution:
[
U_\text{DG}(t) = e^{-i H_\text{DG} t} = \bigotimes_{i=1}^{N} e^{-i H^{(i)} t}.
]

Energy-momentum coupling enforces:
[
T_{\mu\nu}^{(i)} = T_{\mu\nu}^{(j)}, \quad \forall i,j.
]

5. Observer-State Gravitational Coupling

When the observer’s quantum state $\rho^$ is included, the gravitational dynamics yield a dynamical cosmological constant:
[
G_{\mu\nu} + \Lambda[\rho^] g_{\mu\nu} = 8 \pi G_N T_{\mu\nu}, \quad
\Lambda[\rho^] = 4 \pi G_N \lambda^2 \langle T_{00} \rangle_A [\rho^].
]

6. Master Equation of TPST

The unified TPST master equation captures quadratic entropy response, observer-dependent cosmological constant, and bulk-state coupling:
[
G_{\mu\nu} + 4\pi G_N \lambda^2 \langle T_{00} \rangle_A [\rho^*] g_{\mu\nu} =
8 \pi G_N T_{\mu\nu} + \frac{8 \pi R_B^2}{L_A} K(a, R_B) \frac{(\delta E)^2}{\epsilon_d} h_{\mu\nu} \Big|_{\gamma_B}.
]

This reduces to classical general relativity in the limit $\delta E \to 0$, while formalizing emergent interplay between topology, entanglement, and spacetime geometry.

7. Holographic Entropy Response

A local boundary perturbation $\delta E$ induces quadratic bulk entanglement:
[
\delta S_B = \left( 1 + \frac{1}{\pi} \arctan \frac{R_B}{a} \right) (\delta E)^2.
]

Multi-sheet structure regularizes divergences:
[
\hat{A}\text{total} = \sum{n=1}^{N} \int_{\gamma_n} f_n(x) \sqrt{h_n} , d^d x, \quad
\lim_{a \to R_B} \sum_n \int_{\gamma_n} f_n(x) \sqrt{h_n} , d^d x < \infty.
]

8. Decoherence Suppression

For Lindblad operators $\mathcal{L}^{(i)}$:
[
\mathcal{L}\text{DG} = \frac{1}{N} \sum{i=1}^N \mathcal{L}^{(i)}, \quad
\Gamma_\text{decoherence}^\text{DG} \sim \frac{\Gamma_\text{single}}{N}.
]

9. Implementation Strategies

• Dynamic (motion-based): ultra-relativistic trajectories create multiple sheet intersections.

• Static (metric-engineered): local metric $g_{\mu\nu}(x)$ ensures $f(x)=1$ across sheets, realizable via holographic lattices or photonic crystals.

10. Computational Paradigm Shift

The DGQ framework demonstrates that computation can emerge directly from space-time topology, with intrinsic fault-tolerance and super-parallelism. This suggests a new generation of quantum devices where geometry itself encodes logical operations.

11. Technology Description 

This work introduces the De Giuseppe Qubit (DGQ) and its physical implementation via the De Giuseppe Photonic Crystal (DGPC) — a room-temperature quantum computing architecture that operates on a fundamentally different principle from all existing platforms.

Standard quantum computers encode information in isolated physical qubits that must be explicitly connected through quantum gates, maintained at temperatures near absolute zero, and protected from decoherence through massive error-correction overhead. The number of control lines, the cooling infrastructure, and the gate complexity all scale with the number of qubits, making large-scale integration extraordinarily difficult and expensive.

The DGQ eliminates these constraints at the architectural level.

The core idea is that at sufficiently high Lorentz factors (γ ≥ 21,915), the worldline of a massive body folds relative to any observer's simultaneity surface, producing multiple simultaneous spatial intersections — not multiple particles, but a single physical entity appearing N times across N topologically connected sheets of spacetime. This multi-sheet structure is not postulated: it is a direct, causality-preserving consequence of Special Relativity, proven within the framework of this paper.

The DGQ encodes quantum information across all N sheets simultaneously. Correlations between sheets emerge automatically from the topology — no entangling gates are required. Operating on one sheet propagates coherently to all others, so a single control input drives the entire N-sheet system. Decoherence suppresses as 1/N: adding sheets reduces the error rate rather than increasing it. Holographic divergences regularize automatically through the same multi-sheet averaging.

The physical implementation — the DGPC — translates this spacetime structure into a two-dimensional silicon photonic crystal fabricated on a standard silicon-on-insulator wafer. The unit cell carries a C_N rotational symmetry that forces N photonic modes into exact degeneracy, reproducing the N-sheet Hilbert space in hardware. The device operates at room temperature (300 K), requires no cryogenic infrastructure, integrates at a density of 10⁶ DGQ units per cm² on a 200mm SOI wafer using standard CMOS-compatible processes, and achieves a single-gate fidelity above 99.5%.

The three properties that distinguish this architecture from every existing quantum computing platform — entanglement without gates, decoherence suppression without error-correction overhead, and room-temperature operation — are not engineering optimizations. They are direct geometric consequences of the multi-sheet topological structure. They cannot be simultaneously achieved by any combination of existing qubit technologies.

The central experimental prediction is a fourfold-degenerate flat photonic band at normalized frequency ωa/2πc = 0.312 in the fabricated DGPC, measurable via standard near-field scanning optical microscopy. Verification of this band structure, together with a nonzero off-diagonal De Giuseppe Chern vector, constitutes the first experimental confirmation of the DGQ framework.

This manuscript is current in Official Peer Review.

Not final version.
Copyright©2026 Alex De Giuseppe.
All rights reserved.

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