Entanglement Transition due to particle losses in a monitored fermionic chain

• URL: http://arxiv.org/abs/2408.03700v2
• Date: Tue, 14 Jan 2025 16:19:50 GMT
• Title: Entanglement Transition due to particle losses in a monitored fermionic chain
• Authors: Rafael D. Soares, Youenn Le Gal, Marco Schirò,
• Abstract summary: We study the dynamics of the entanglement entropy scaling under quantum entanglement jumps. We show that by tuning the system parameters, a measurement-induced transition occurs where the entanglement entropy changes from logarithmic to area-law.
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• Abstract: Recently, there has been interest in the dynamics of monitored quantum systems using linear jump operators related to the creation or annihilation of particles. Here, we study the dynamics of the entanglement entropy under quantum jumps that induce local particle losses in a model of free fermions with hopping and $\mathbb{Z}_2$ pairing. We solve the non-unitary dynamics using the recently developed Faber Polynomial method and explore the different steady-state entanglement regimes by tuning the pairing strength, thus interpolating between monitored free fermions coherently driven by a particle number conserving Hamiltonian to a parity conserving one. In the absence of pairing, all quantum trajectories approach the vacuum at long times, with the entanglement entropy showing non-monotonic behavior over time that we capture with a phenomenological quasiparticle \emph{ansatz}. In this regime, quantum jumps play a key role, and we highlight this by exactly computing their waiting-time distribution. On the other hand, the interplay between losses and pairing gives rise to quantum trajectories with entangled steady-states. We show that by tuning the system parameters, a measurement-induced entanglement transition occurs where the entanglement entropy scaling changes from logarithmic to area-law. We compare this transition with the one derived in the no-click limit and observe qualitative agreement in most of the phase diagram. Furthermore, the statistics of entanglement gain and loss are analyzed to better understand the impact of the linear jump operators.

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