Variety of Superradiant Phase Transition in Bose-Fermi System with Tight-Binding Model in the weak-coupling regime

• URL: http://arxiv.org/abs/2503.02226v1
• Date: Tue, 04 Mar 2025 03:04:35 GMT
• Title: Variety of Superradiant Phase Transition in Bose-Fermi System with Tight-Binding Model in the weak-coupling regime
• Authors: Xing Su, Jian-Jian Cheng, Lin Zhang,
• Abstract summary: We explore the dynamic diversity inherent in superradiant phase transitions within a one-dimensional tight-binding electronic chain.<n>By employing a quantized electromagnetic vector potential via the Peierls substitution, this gauge-coupled Bose-Fermi system facilitates momentum-dependent superradiant transitions.
• Score: 5.581287929903093
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: We present a full exploration of the dynamic diversity inherent in superradiant phase transitions within a one-dimensional tight-binding electronic chain that is intricately coupled to a single-mode optical cavity. By employing a quantized electromagnetic vector potential via the Peierls substitution, this gauge-coupled Bose-Fermi system facilitates momentum-dependent superradiant transitions. These transitions are characterized by the displacement of the cavity mode and the redistribution of electronic momentum, thereby circumventing the second-order spurious phase transitions typically observed in Dicke-like models. Distinct from multimode cavity QED systems with atomic gases, the single-mode optical configuration unveils a range of nonlinear phenomena, including multistability and varied spontaneous symmetry breaking. This configuration enables the precise manipulation of superradiant phases in weak coupling regimes, devoid of the quantum fluctuation divergence. Our findings advance the understanding of tunable quantum devices and highlight potential applications in quantum information processing and metrology.

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