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arxiv: 2312.14022 · v1 · pith:5WFFEQCJnew · submitted 2023-12-21 · 🪐 quant-ph · cond-mat.dis-nn· cond-mat.mes-hall· cond-mat.str-el

Theory of free fermions dynamics under partial post-selected monitoring

classification 🪐 quant-ph cond-mat.dis-nncond-mat.mes-hallcond-mat.str-el
keywords post-selecteddynamicspartialfinitemiptsmonitoredapproachfermions
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Monitored quantum systems undergo Measurement-induced Phase Transitions (MiPTs) stemming from the interplay between measurements and unitary dynamics. When the detector readout is post-selected to match a given value, the dynamics is generated by a Non-Hermitian Hamiltonian with MiPTs characterized by different universal features. Here, we derive a partial post-selected stochastic Schr\"odinger equation based on a microscopic description of continuous weak measurement. This formalism connects the monitored and post-selected dynamics to a broader family of stochastic evolution. We apply the formalism to a chain of free fermions subject to partial post-selected monitoring of local fermion parities. Within a 2-replica approach, we obtained an effective bosonized Hamiltonian in the strong post-selected limit. Using a renormalization group analysis, we find that the universality of the non-Hermitian MiPT is stable against a finite (weak) amount of stochasticity. We further show that the passage to the monitored universality occurs abruptly at finite partial post-selection, which we confirm from the numerical finite size scaling of the MiPT. Our approach establishes a way to study MiPTs for arbitrary subsets of quantum trajectories and provides a potential route to tackle the experimental post-selected problem.

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Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. Controlling Waiting Time Statistics in Monitored Collective Spins: Mitigating Detector's Resolution Barrier in Measurement-Induced Phase Transitions

    quant-ph 2026-07 unverdicted novelty 5.0

    Partitioning monitored collective spins into subsystems rotated by θ increases jump waiting times by orders of magnitude, fully resolving detector resolution at θ=π while lengthening entanglement saturation.