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Autores principales: Dong, Yichen, Demler, Eugene, Sun, Zhiyuan
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2512.21097
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author Dong, Yichen
Demler, Eugene
Sun, Zhiyuan
author_facet Dong, Yichen
Demler, Eugene
Sun, Zhiyuan
contents In Wigner-crystal states of two-dimensional electrons, the spin ordering remains poorly understood. The small energy differences between candidate spin orders make theoretical studies less reliable, and probing magnetic order at a nonzero wave vector is experimentally challenging. In modern realizations of Wigner crystals, the electronic spin degree of freedom is often replaced by a valley pseudospin associated with nonzero Berry curvature. The resulting anomalous velocity couples the electrons' pseudospin texture to their orbital vibration. We show that this mechanism enables optical detection of pseudospin orders in Wigner crystals by producing sharp signatures in the terahertz optical conductivity. For example, antiferromagnetic pseudospin order enables light to excite collective electronic vibrations at the ordering wave vector, generating a characteristic absorption peak. Based on the same principle, we further show that a strong optical drive generates an effective potential that reshapes the pseudospin energy landscape, inducing phase transitions to stripe antiferromagnetic states. These results point to a route for optical detection and control of spin order via its coupling to orbital motion.
format Preprint
id arxiv_https___arxiv_org_abs_2512_21097
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Optical Detection and Manipulation of Pseudospin Orders in Wigner Crystals
Dong, Yichen
Demler, Eugene
Sun, Zhiyuan
Strongly Correlated Electrons
In Wigner-crystal states of two-dimensional electrons, the spin ordering remains poorly understood. The small energy differences between candidate spin orders make theoretical studies less reliable, and probing magnetic order at a nonzero wave vector is experimentally challenging. In modern realizations of Wigner crystals, the electronic spin degree of freedom is often replaced by a valley pseudospin associated with nonzero Berry curvature. The resulting anomalous velocity couples the electrons' pseudospin texture to their orbital vibration. We show that this mechanism enables optical detection of pseudospin orders in Wigner crystals by producing sharp signatures in the terahertz optical conductivity. For example, antiferromagnetic pseudospin order enables light to excite collective electronic vibrations at the ordering wave vector, generating a characteristic absorption peak. Based on the same principle, we further show that a strong optical drive generates an effective potential that reshapes the pseudospin energy landscape, inducing phase transitions to stripe antiferromagnetic states. These results point to a route for optical detection and control of spin order via its coupling to orbital motion.
title Optical Detection and Manipulation of Pseudospin Orders in Wigner Crystals
topic Strongly Correlated Electrons
url https://arxiv.org/abs/2512.21097