Sector-memory obstruction to probe-level bath emergence in finite programmable qubit environments

Abstract

Finite quantum environments can relax local probes without acting as canonical baths. We study this distinction for a probe qubit coupled to a programmable bath of (N) qubits under excitation-number-conserving dynamics. The conserved charge partitions the Hilbert space into sectors. We characterize probe-level bath emergence using the sector-resolved late-time population (pe(q)), the sector-memory variance (MN), and a global Gibbs-fit error (ΔGglobal). Exact simulations with Haar-random pure states in each complete fixed-charge sector yield sector-dependent populations close to the maximally mixed-sector benchmark (pe(q)=q/(N+1)), producing a nonzero Gibbs obstruction. We then construct charge-preserving Floquet circuits using (Rz) phases and (XX+YY) exchange gates, validate them with ideal and noisy Qiskit simulations, and implement finite-depth experiments on IBM Fez. For (N=4) and (ε=0), the hardware data give (MN 0.044), (ΔGglobal 0.558), and charge preservation near 0.90 after readout mitigation. A paired symmetry-breaking scan using bath (Rx(ε)) rotations reduces both diagnostics while increasing charge leakage, but does not erase sector ordering over the accessible depths. These results show that equilibration within constrained sectors is insufficient to produce a single sector-independent Gibbs state for the probe.

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