Package 24 — Qubit decoherence as UTAC threshold system (GenesisAeon Entropy Atlas)
Project description
quantum-genesis
Qubit decoherence as a UTAC threshold system — Package 24 of the GenesisAeon Entropy Atlas.
Models superconducting qubit decoherence via the CREP (Coherence–Resonance–Emergence–Poetics) framework, coupling the QEC threshold theorem to the Unified Threshold Adaptive Criticality (UTAC) system.
Central result: Γ_quantum ≈ 0.050 — qubits are the most fragile UTAC system in the Entropy Atlas (just above solar magnetic flares at Γ ≈ 0.014). This quantifies why quantum computing is extraordinarily difficult: any perturbation can cross the phase boundary.
CREP Criticality Spectrum — quantum-genesis in context
| Domain | Package | Γ | Note |
|---|---|---|---|
| Solar flare magnetic field | P21 | 0.014 | Ultra-sensitive |
| Cygnus X-1 jet | P17 | 0.046 | Hair-trigger |
| Qubit decoherence (T2) | P24 | 0.050 | ← quantum-genesis |
| Apoptosis ATP threshold | P25 | 0.090 | Cellular critical |
| Amazon rainforest | P19 | 0.116 | Ecological fragile |
| Neural criticality / AMOC | P18/P20 | 0.251 | Homeostatic universal |
Physical Mapping to UTAC
H(t) ← coherence fraction = (1 − p_error) ∈ [0, 1]
K ← 1.0 (perfect coherence ceiling)
H* ← 1 − p_threshold ≈ 0.999 (QEC phase boundary)
r ← 0.10 (coherence improvement rate per generation)
σ ← 2.2 (universal CREP coupling)
CREP tensor components:
| Symbol | Meaning |
|---|---|
| C | Off-diagonal density matrix coherence |ρ₀₁| |
| R | Proximity of error rate to QEC threshold (resonance at p_th) |
| E | Logical vs. physical error rate ratio (emergent QEC benefit) |
| P | Entropy of T1 distribution / logical depth efficiency |
Phase transition: The QEC threshold at p_th ≈ 10⁻³ is the UTAC phase boundary. Below threshold → stable logical qubit. Above threshold → decoherence cascade. At threshold → information critical phase (Vijay & Lee 2026): fractional logical qubit preservation f ≈ 0.25.
Installation
pip install quantum-genesis
# or
uv add quantum-genesis
# Optional backends
pip install quantum-genesis[sim] # stim + qiskit-ibm-runtime
Quickstart
from quantum_genesis import QuantumGenesis
qg = QuantumGenesis(t1_us=100.0) # Google Willow reference T1
# Run 1000 QEC syndrome cycles
result = qg.run_cycle(n_syndrome_cycles=1000)
print(result)
# {'n_syndrome_cycles': 1000, 'crep': {'C': ..., 'R': ..., 'E': ..., 'P': ..., 'Gamma': 0.049...}, ...}
# Diamond interface
print(qg.get_crep_state()) # {C, R, E, P, Gamma}
print(qg.get_utac_state()) # {H, dH_dt, H_star, K_eff}
print(qg.get_phase_events()) # decoherence cascade events
print(qg.is_below_threshold()) # True
print(qg.logical_error_rate(d=7)) # surface code d=7
print(qg.gamma_quantum()) # ≈ 0.050
# Zenodo metadata record
record = qg.to_zenodo_record()
Diamond Interface Contract
All GenesisAeon packages implement this interface:
class QuantumGenesis:
def run_cycle(self, n_syndrome_cycles: int = 1000) -> dict: ...
def get_crep_state(self) -> dict: # {C, R, E, P, Gamma}
def get_utac_state(self) -> dict: # {H, dH_dt, H_star, K_eff}
def get_phase_events(self) -> list: # logical error events
def to_zenodo_record(self) -> dict: # Zenodo-compatible metadata
Benchmark Targets
| Metric | Target | Tolerance | Source |
|---|---|---|---|
| QEC threshold [%] | 0.100 | ±0.03 | Surface code theory |
| Google Willow T1 [µs] | 100.0 | ±30% | Willow 2024 |
| Logical depth L_d | 1.615 | ±0.05 | Ibnouhsein 2025 |
| R² (T1 from topology) | 0.96 | ±0.02 | npj QI 2026 |
| Γ_quantum | 0.050 | ±0.010 | CREP calibration |
| Info. critical fraction | 0.25 | ±0.10 | Vijay & Lee 2026 |
Run benchmarks:
from quantum_genesis.benchmark import run_benchmark, print_benchmark_report
results = run_benchmark()
print_benchmark_report(results)
Repository Structure
quantum-genesis/
├── src/quantum_genesis/
│ ├── system.py # QuantumGenesis — Diamond interface
│ ├── qubit_model.py # T1/T2 decay + TLS fluctuation model
│ ├── density_matrix.py # Lindblad density matrix evolution
│ ├── qec_threshold.py # Surface code threshold analysis
│ ├── toric_code.py # Information critical phase (Vijay & Lee 2026)
│ ├── topology_features.py # 14 graph features → T1 prediction (npj 2026)
│ ├── crep_quantum.py # Quantum CREP tensor
│ ├── logical_depth.py # Logical depth L_d (Ibnouhsein 2025)
│ ├── stim_interface.py # stim surface code simulator (optional)
│ ├── benchmark.py # Literature benchmark targets
│ └── constants.py
├── notebooks/
│ ├── 01_qubit_utac_overview.ipynb
│ ├── 02_qec_threshold_phase_transition.ipynb
│ ├── 03_information_critical_phase.ipynb
│ ├── 04_logical_depth_entropy.ipynb
│ └── 05_gamma_quantum_calibration.ipynb
├── data/
│ ├── ibm_quantum_t1_public.yaml
│ └── willow_2024_targets.yaml
└── src/diamond_setup/ # scaffold tool (diamond-setup v1.0.0)
References
-
Ibnouhsein 2025 — Thermodynamic signature of logical depth in quantum circuits. Foundations of Physics 55, 71. DOI: 10.1007/s10701-025-00883-w
-
npj Quantum Information 2026 — Machine learning decoherence from graph connectivity. DOI: 10.1038/s41534-026-01199-x R² > 0.96 for T1 prediction from 14 topological features.
-
Vijay & Lee 2026 — Decoherence enables information critical phases. Fractional topological memory in decohered Toric codes.
-
Google Willow 2024 — Below-threshold QEC demonstrated. Logical error rate decreases exponentially with code distance.
-
GenesisAeon Whitepaper — DOI: 10.5281/zenodo.19645351
Falsifiable Prediction
As T1 improves toward 1 ms (next-generation qubits), Γ_quantum will increase from 0.050 toward 0.100, placing quantum systems in the "cellular critical" range — equivalent to the apoptosis ATP threshold (Package 25). Testable against IBM Quantum roadmap milestones (public).
Citation
DOI will be assigned automatically on first GitHub Release once
Zenodo–GitHub integration is enabled for this repo. (The whitepaper DOI
below, 10.5281/zenodo.19645351, already exists and documents the
package's scientific model; the software-specific DOI is separate and
versioned per release.)
@software{romer_quantum_genesis_2026,
author = {Römer, Johann and MOR Research Collective},
title = {quantum-genesis: Qubit Decoherence as UTAC Threshold System},
year = {2026},
publisher = {Zenodo},
version = {0.1.0},
doi = {10.5281/zenodo.19645351},
url = {https://doi.org/10.5281/zenodo.19645351}
}
GenesisAeon Entropy Atlas · Package 24 of 30 · Johann Römer · MOR Research Collective · 2026
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