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Main Authors: Villa, Greta, del Pino, Javier, Dumont, Vincent, Rastelli, Gianluca, Michałek, Mateusz, Eichler, Alexander, Zilberberg, Oded
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2406.16591
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author Villa, Greta
del Pino, Javier
Dumont, Vincent
Rastelli, Gianluca
Michałek, Mateusz
Eichler, Alexander
Zilberberg, Oded
author_facet Villa, Greta
del Pino, Javier
Dumont, Vincent
Rastelli, Gianluca
Michałek, Mateusz
Eichler, Alexander
Zilberberg, Oded
contents In topology, one averages over local geometrical details to reveal robust global features. This approach proves crucial for understanding quantized bulk transport and exotic boundary effects of linear wave propagation in (meta-)materials. Moving beyond linear Hamiltonian systems, the study of topology in physics strives to characterize open (non-Hermitian) and interacting systems. Here, we establish a framework for the topological classification of driven-dissipative nonlinear systems. Specifically, we define a graph index for the Floquet semiclassical equations of motion describing such systems. The graph index builds upon topological vector analysis theory and combines knowledge of the particle-hole nature of fluctuations around each out-of-equilibrium stationary state. To test this approach, we divulge the topological invariants arising in a micro-electromechanical nonlinear resonator subject to forcing and a time-modulated potential. Our framework classifies the complete phase diagram of the system and reveals the topological origin of driven-dissipative phase transitions, as well as that of under- to over-damped responses. Furthermore, we predict topological phase transitions between symmetry-broken phases that pertain to population inversion transitions. This rich manifesting phenomenology reveals the pervasive link between topology and nonlinear dynamics, with broad implications for all fields of science.
format Preprint
id arxiv_https___arxiv_org_abs_2406_16591
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Topological classification of driven-dissipative nonlinear systems
Villa, Greta
del Pino, Javier
Dumont, Vincent
Rastelli, Gianluca
Michałek, Mateusz
Eichler, Alexander
Zilberberg, Oded
Mesoscale and Nanoscale Physics
In topology, one averages over local geometrical details to reveal robust global features. This approach proves crucial for understanding quantized bulk transport and exotic boundary effects of linear wave propagation in (meta-)materials. Moving beyond linear Hamiltonian systems, the study of topology in physics strives to characterize open (non-Hermitian) and interacting systems. Here, we establish a framework for the topological classification of driven-dissipative nonlinear systems. Specifically, we define a graph index for the Floquet semiclassical equations of motion describing such systems. The graph index builds upon topological vector analysis theory and combines knowledge of the particle-hole nature of fluctuations around each out-of-equilibrium stationary state. To test this approach, we divulge the topological invariants arising in a micro-electromechanical nonlinear resonator subject to forcing and a time-modulated potential. Our framework classifies the complete phase diagram of the system and reveals the topological origin of driven-dissipative phase transitions, as well as that of under- to over-damped responses. Furthermore, we predict topological phase transitions between symmetry-broken phases that pertain to population inversion transitions. This rich manifesting phenomenology reveals the pervasive link between topology and nonlinear dynamics, with broad implications for all fields of science.
title Topological classification of driven-dissipative nonlinear systems
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2406.16591