Generalized Gibbs ensembles in weakly interacting dissipative systems and digital quantum computers

• URL: http://arxiv.org/abs/2406.17033v1
• Date: Mon, 24 Jun 2024 18:00:11 GMT
• Title: Generalized Gibbs ensembles in weakly interacting dissipative systems and digital quantum computers
• Authors: Iris Ulčakar, Zala Lenarčič,
• Abstract summary: We propose using a digital quantum computer to showcase the activation of integrability. Dissipation is realized by coupling system's qubits to periodically reset ancilla ones. We derive the effective equations of motion for trotterized dynamics.
• Score: 0.0
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Digital quantum computers promise to solve important and challenging problems in many-body quantum physics. However, at least for the superconducting platforms, their current limitation is the noise level. It thus seems more reasonable to presently use them to model dissipative systems, where platforms' native noise is not that crucial. Here, we propose using a digital quantum computer to showcase the activation of integrability by realizing exotic generalized Gibbs ensembles in weakly dissipative integrable systems. Dissipation is realized by coupling system's qubits to periodically reset ancilla ones, like in the protocol recently used to realize dissipative cooling. We derive the effective equations of motion for trotterized dynamics and contrast such a setup to the usual Lindblad continuous evolution. For simplicity, we consider and compare different approaches to calculating steady-states of non-interacting integrable systems weakly coupled to baths, where thermodynamic results can be obtained via a generalized scattering theory between the Bogoliubov quasiparticles. Corresponding quantum computer implementation would illuminate the possibilities of realizing similar exotic states in nearly integrable quantum materials.

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