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Auteurs principaux: Zhang, Ren, Ouyang, Xiao-Yu, Dai, Xu-Dong, Dai, Xi
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2601.19991
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author Zhang, Ren
Ouyang, Xiao-Yu
Dai, Xu-Dong
Dai, Xi
author_facet Zhang, Ren
Ouyang, Xiao-Yu
Dai, Xu-Dong
Dai, Xi
contents We establish a scattering-state theory for open one-dimensional Floquet lattices based on a frequency-domain transfer-matrix formulation. For real quasienergy, the conjugate-symplectic structure of the transfer matrix separates bulk Floquet--Bloch modes into propagating and evanescent sectors, enabling a consistent treatment of interface matching and the shrinking-window smoothing required for long-sample transport. By tracking how incoming states populate deep-bulk propagating branches, we define branch-resolved weights \(p_{μα}\) and total branch weights \(p_μ\). We prove that \(p_μ\) equals the escape probability of a wave packet initialized on the corresponding branch. In the open geometries considered here, true bound trapping of propagating branches is nongeneric, yielding \(p_μ=1\) for generic parameters. This generic openness implies that long-sample transport is governed by deep-bulk branch populations rather than by boundary-sensitive interference. Consequently, the integrated left--right transmission asymmetry reduces to the net chirality, and hence the winding contribution, of an isolated Floquet band. The robust topological observable is therefore the accumulated asymmetry plateau, not the detailed transmission line shape, which remains strongly reshaped by nonadiabatic boundaries. A spatially adiabatic boundary serves only as a transparent benchmark for resolving the branch structure, not as the origin of the topological response.
format Preprint
id arxiv_https___arxiv_org_abs_2601_19991
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Scattering-state theory of open Floquet lattices: transfer matrices, branch openness, and robust asymmetry
Zhang, Ren
Ouyang, Xiao-Yu
Dai, Xu-Dong
Dai, Xi
Mesoscale and Nanoscale Physics
Quantum Gases
Quantum Physics
We establish a scattering-state theory for open one-dimensional Floquet lattices based on a frequency-domain transfer-matrix formulation. For real quasienergy, the conjugate-symplectic structure of the transfer matrix separates bulk Floquet--Bloch modes into propagating and evanescent sectors, enabling a consistent treatment of interface matching and the shrinking-window smoothing required for long-sample transport. By tracking how incoming states populate deep-bulk propagating branches, we define branch-resolved weights \(p_{μα}\) and total branch weights \(p_μ\). We prove that \(p_μ\) equals the escape probability of a wave packet initialized on the corresponding branch. In the open geometries considered here, true bound trapping of propagating branches is nongeneric, yielding \(p_μ=1\) for generic parameters. This generic openness implies that long-sample transport is governed by deep-bulk branch populations rather than by boundary-sensitive interference. Consequently, the integrated left--right transmission asymmetry reduces to the net chirality, and hence the winding contribution, of an isolated Floquet band. The robust topological observable is therefore the accumulated asymmetry plateau, not the detailed transmission line shape, which remains strongly reshaped by nonadiabatic boundaries. A spatially adiabatic boundary serves only as a transparent benchmark for resolving the branch structure, not as the origin of the topological response.
title Scattering-state theory of open Floquet lattices: transfer matrices, branch openness, and robust asymmetry
topic Mesoscale and Nanoscale Physics
Quantum Gases
Quantum Physics
url https://arxiv.org/abs/2601.19991