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Bibliographic Details
Main Authors: Shin, Dongbin, Lu, I-Te, Fan, Benshu, Bostrom, Emil Vinas, Liu, Hang, Svendsen, Mark Kamper, Latini, Simone, Tang, Peizhe, Rubio, Angel
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.23494
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author Shin, Dongbin
Lu, I-Te
Fan, Benshu
Bostrom, Emil Vinas
Liu, Hang
Svendsen, Mark Kamper
Latini, Simone
Tang, Peizhe
Rubio, Angel
author_facet Shin, Dongbin
Lu, I-Te
Fan, Benshu
Bostrom, Emil Vinas
Liu, Hang
Svendsen, Mark Kamper
Latini, Simone
Tang, Peizhe
Rubio, Angel
contents Strong light-matter interactions can be exploited to modify properties of quantum materials both in and out of thermal equilibrium. Recent studies suggest electromagnetic fields in photonic structures can hybridize with condensed matter systems, resulting in photon field-dressed collective quantum states such as charge density waves, superconductivity, and ferroelectricity. Here, we show that photon fields in photonic structures, including optical cavities and waveguides, induce emergent topological phases in solids through polarization-mediated symmetry-breaking mechanisms. Using state-of-the-art quantum electrodynamic density functional theory (QEDFT) calculations, we demonstrate that strong light-matter coupling can reconfigure both the electronic and ionic structures of HgTe, driving the system into Weyl, nodal-line, or topological insulator phases. These phases depend on the relative orientation of the sample in the photonic structures, as well as the coupling strength. Unlike previously reported laser-driven phenomena with ultrashort lifetimes, the photon field-induced symmetry breaking arises from steady-state photon-matter hybridization, enabling multiple robust topological states to emerge. Our study demonstrates that vacuum fluctuations in photonic structures can be used to engineer material properties and realize rich topological phenomena in quantum materials on demand.
format Preprint
id arxiv_https___arxiv_org_abs_2506_23494
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Multiple Photon Field-induced Topological States in Bulk HgTe
Shin, Dongbin
Lu, I-Te
Fan, Benshu
Bostrom, Emil Vinas
Liu, Hang
Svendsen, Mark Kamper
Latini, Simone
Tang, Peizhe
Rubio, Angel
Materials Science
Strong light-matter interactions can be exploited to modify properties of quantum materials both in and out of thermal equilibrium. Recent studies suggest electromagnetic fields in photonic structures can hybridize with condensed matter systems, resulting in photon field-dressed collective quantum states such as charge density waves, superconductivity, and ferroelectricity. Here, we show that photon fields in photonic structures, including optical cavities and waveguides, induce emergent topological phases in solids through polarization-mediated symmetry-breaking mechanisms. Using state-of-the-art quantum electrodynamic density functional theory (QEDFT) calculations, we demonstrate that strong light-matter coupling can reconfigure both the electronic and ionic structures of HgTe, driving the system into Weyl, nodal-line, or topological insulator phases. These phases depend on the relative orientation of the sample in the photonic structures, as well as the coupling strength. Unlike previously reported laser-driven phenomena with ultrashort lifetimes, the photon field-induced symmetry breaking arises from steady-state photon-matter hybridization, enabling multiple robust topological states to emerge. Our study demonstrates that vacuum fluctuations in photonic structures can be used to engineer material properties and realize rich topological phenomena in quantum materials on demand.
title Multiple Photon Field-induced Topological States in Bulk HgTe
topic Materials Science
url https://arxiv.org/abs/2506.23494