Monitored long-range interacting systems: spin-wave theory for quantum trajectories

• URL: http://arxiv.org/abs/2405.12124v1
• Date: Mon, 20 May 2024 15:41:38 GMT
• Title: Monitored long-range interacting systems: spin-wave theory for quantum trajectories
• Authors: Zejian Li, Anna Delmonte, Xhek Turkeshi, Rosario Fazio,
• Abstract summary: We introduce a spin-wave theory tailored to describe quantum trajectories in continuously monitored long-range interacting spin systems. Our method, based on the bosonization of spin-wave excitations on top of a strong collective polarization, enables the efficient simulation of large-scale interacting spins.
• Score: 3.9162186116762596
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: We introduce a stochastic spin-wave theory tailored to describe quantum trajectories in continuously monitored long-range interacting spin systems. Our method, based on the bosonization of spin-wave excitations on top of a strong collective polarization, enables the efficient simulation of large-scale interacting spins, offering insights into nonlinear features of the dynamics such as entanglement and trajectory correlations. We showcase the versatility of our framework by exploring an entanglement phase transition in a monitored spin system with power-law interactions and dwelling on how our method mitigates the experimental challenges of post-selection in detecting monitored quantum phases.

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