Characterizing generalized Floquet topological states in hybrid space-time dimensions

arXiv - PHYS - Applied Physics Pub Date : 2024-09-16 DOI:arxiv-2409.09937

Weiwei Zhu, Jian-Hua Jiang

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引用次数: 0

Abstract

In spatiotemporally modulated systems, topological states exist not only in energy gaps but also in momentum gaps. Such unconventional topological states impose challenges on topological physics. The underlying models also make the conventional Hamiltonian descriptions complicated. Here, we propose to describe such systems with space- and time-direction transfer matrices which substantially simplify the underlying theory and give direct information on the topological properties of the quasienergy and quasimomentum gaps. In particular, we find that the space- and time-direction reflection phases can serve as signatures for distinguishing various topological phases of the quasienergy and quasimomentum gaps. This approach directly reveals the topological properties of the band gap, avoiding the complexity in calculating bulk band topology in hybrid energy-moment space. By investigating two concrete models, we show that the method works well for both Hermitian and non-Hermitian systems. Furthermore, we uncover an unconventional topological state, called the anomalous Floquet quasimomentum gap, whose topological properties are invariant for different choices of the unit-cell center. This work advances the study of topological phenomena in hybrid space-time (energy-momentum) dimension that are attracting much interest due to the development of spatiotemporally modulated materials.

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描述混合时空维度中的广义 Floquet 拓扑态

在时空调制系统中，拓扑态不仅存在于能量隙中，也存在于动量隙中。这种非常规拓扑态给拓扑物理学带来了挑战。其基础模型也使传统的哈密顿描述变得复杂。在这里，我们提出用空间和时间方向的转移矩阵来描述这类系统，这大大简化了基础理论，并直接给出了准能隙和准动量隙的拓扑性质。特别是，我们发现空间和时间方向的反射相位可以作为区分准能隙和准动隙的各种拓扑相位的标志。这种方法直接揭示了带隙的拓扑特性，避免了在混合能矩空间中计算大块带拓扑的复杂性。通过对两个具体模型的研究，我们表明这种方法对赫米和非赫米系统都很有效。此外，我们还发现了一种非常规的拓扑状态，即反常的弗洛克准动量隙，其拓扑性质在不同的单元中心选择下是不变的。这项工作推动了对混合时空（能量-动量）维度拓扑现象的研究，由于时空调制材料的发展，这种拓扑现象正引起人们的极大兴趣。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Applied Physics

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