Related papers: Unconventional Floquet topological phases in the SSH lattice

Unconventional Floquet topological phases in the SSH lattice

URL: http://arxiv.org/abs/2507.16441v1
Date: Tue, 22 Jul 2025 10:34:58 GMT
Title: Unconventional Floquet topological phases in the SSH lattice
Authors: Dunkan Martínez, Yuriko Baba, Benjamín Santos, Rodrigo P. A. Lima, Pedro Orellana, Francisco Domínguez-Adame, Alexander López,
Abstract summary: Topological materials, known for their edge states robust against local perturbations, hold promise for next-generation quantum technologies.<n>We propose to use high-frequency monochromatic driving and modulated amplitude pulses to dynamically induce and switch the Floquet topological phases.
Score: 36.136619420474766
License: http://creativecommons.org/licenses/by-nc-nd/4.0/
Abstract: Topological materials, known for their edge states robust against local perturbations, hold promise for next-generation quantum technologies, but remain scarce in nature and challenging to realize in static systems. The Su-Schrieffer-Heeger chain is a one-dimensional system for topological phases, although its static control is limited. To overcome these limitations, we propose to use high-frequency monochromatic driving and modulated amplitude pulses to dynamically induce and switch the Floquet topological phases. Using a Kramers-Henneberger-like transformation, we encode all Floquet sidebands into a single effective Hamiltonian. We demonstrate that both monochromatic and experimental pulse protocols (Gaussian and fast-beating envelopes) can induce topological edge states, enabling dynamic phase switching. Notably, fast-beating modulations require significantly lower field strengths than monochromatic ones, especially with larger inter-dimer separations. Our findings offer an experimentally feasible route for Floquet engineering, paving the way for ultrafast and energy efficient control of topological phases in quantum platforms, opening up new possibilities in the field of dynamic quantum materials.

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