Non-Hermitian Quantum Metrology Enhancement and Skin Effect Suppression in PT-Symmetric Bardeen-Cooper-Schrieffer Chains

Abstract

We outline a theoretical framework for quantum metrology in non-Hermitian systems, demonstrating both significant failure and exceptional regimes in PT-symmetric Bardeen-Cooper-Schrieffer chains. Through biorthogonal quantum Fisher information analysis, we identify two distinct regimes: exponential sensitivity suppression in the non-Hermitian skin effect phase (FQ N3 e-2κN) where eigenstates localize exponentially, and quadratic enhancement near PT-breaking exceptional points [1-4] (FQ N2/δ) achieving Heisenberg scaling. Our multiparameter analysis establishes optimal simultaneous estimation of chemical potential, Peierls phase, and gain/loss strength with quantum Fisher information matrix scaling as N2, surpassing the standard quantum limit by factors exceeding 102. For realistic parameters (t/2π=10 MHz, Δ/2π=1 MHz, N=50), we predict enhancement factors ημ≈ 20N=141 for chemical potential estimation and ηϕ≈ t2 3N/2=100N over classical sensing. These results are validated through exact finite-size calculations and provide concrete protocols for superconducting circuit implementations.We reveal a core dichotomy in non-Hermitian quantum metrology: NHSE suppresses sensitivity exponentially, while PT-symmetry enables Heisenberg-limited enhancement -- each arising from distinct spectral and localization topologies.