Stability of Floquet sidebands and quantum coherence in 1D strongly interacting spinless fermions

• URL: http://arxiv.org/abs/2502.12643v1
• Date: Tue, 18 Feb 2025 08:50:21 GMT
• Title: Stability of Floquet sidebands and quantum coherence in 1D strongly interacting spinless fermions
• Authors: Karun Gadge, Salvatore R. Manmana,
• Abstract summary: We investigate the impact of electron-electron interactions and perturbations in the coherence of the driving on the lifetime of Floquet-Bloch sidebands. We find for a chain of interacting spinless fermions that high-frequency driving leads to long-lived FBs of the full many-body excitation. In the low-frequency regime and in the presence of noise, heating dominates, resulting in a significant loss of quantum coherence.
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• Abstract: For strongly correlated quantum systems, fundamental questions about the formation and stability of Floquet-Bloch sidebands (FBs) upon periodic driving remain unresolved. Here, we investigate the impact of electron-electron interactions and perturbations in the coherence of the driving on the lifetime of FBs by directly addressing these questions in time-dependent single-particle spectral functions. Using exact diagonalization (ED) and matrix product states (MPS), we find for a chain of interacting spinless fermions that high-frequency driving leads to long-lived FBs of the full many-body excitation continuum, accompanied by in-gap modes related to mobile domain walls. Conversely, in the low-frequency regime and in the presence of noise, heating dominates, resulting in a significant loss of quantum coherence. This is further elucidated by the behaviour of real-space single-particle propagators, of the energy gain, and of the momentum distribution function, which is related to a quantum Fisher information that is directly accessible by spectroscopic measurements.

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