Parallel quench and dynamic geometrical order parameter
- URL: http://arxiv.org/abs/2410.17940v1
- Date: Wed, 23 Oct 2024 15:07:08 GMT
- Title: Parallel quench and dynamic geometrical order parameter
- Authors: Jia-Chen Tang, Xu-Yang Hou, Hao Guo,
- Abstract summary: We show that for certain non-Bloch band models, a simpler quantity can also characterize the geometric changes accompanying DQPTs.
We illustrate these properties in detail through examples involving two-level systems and spin-$j$ systems.
- Score: 1.8605378372249577
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Dynamical quantum phase transitions (DQPTs), while reflecting the characteristics of the dynamical evolution of nonequilibrium quantum systems, can also capture the geometric and topological effects of these system. For band systems, it has been found that the dynamic topological order parameter (DTOP) can describe the accompanying changes in the topological properties of the system when a DQPT occurs. In this paper, we demonstrate that for certain non-Bloch band models, a simpler quantity can also characterize the geometric changes accompanying DQPTs, provided the associated parallel-transport condition is satisfied. At zero temperature, this quantity is the Pancharatnam geometric phase, while at finite temperatures, it is generalized to the interferometric geometric phase. Notably, no dynamical phase is generated during this type of post-quench dynamical evolution. We illustrate these properties in detail through examples involving two-level systems and spin-$j$ systems. These findings provide new insights into understanding the geometric properties of quantum dynamical evolution.
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