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Main Authors: Sethi, Gurjyot, Ruan, Jiawei, Zhang, Fang, Tang, Weichen, Hu, Chen, Naik, Mit, Louie, Steven G.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.07284
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author Sethi, Gurjyot
Ruan, Jiawei
Zhang, Fang
Tang, Weichen
Hu, Chen
Naik, Mit
Louie, Steven G.
author_facet Sethi, Gurjyot
Ruan, Jiawei
Zhang, Fang
Tang, Weichen
Hu, Chen
Naik, Mit
Louie, Steven G.
contents Combining magnetometry with optical spectroscopy has uncovered novel quantum phenomena and is emerging as a platform for quantum information science. Yet, the theory of magnetic response of excitons, correlated electron-hole pairs in semiconductors, remains incomplete due to insufficient treatment of electron-hole interaction and topological effects. In biased bilayer graphene, for instance, theoretical predictions of valley g-factor for p-excitons deviate from experiment by nearly an order of magnitude. Here, we develop a quantum theory of exciton orbital magnetic moment that reveals several conceptually new terms absent in prior theories, including an unforeseen contribution from exciton band quantum geometry. Our ab initio calculations yield results in excellent agreement with measurements, establishing the importance of a full theory including interaction and topological effects for the magnetic response of excitons.
format Preprint
id arxiv_https___arxiv_org_abs_2509_07284
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Quantum Theory of Exciton Magnetic Moment: Interaction and Topological Effects
Sethi, Gurjyot
Ruan, Jiawei
Zhang, Fang
Tang, Weichen
Hu, Chen
Naik, Mit
Louie, Steven G.
Mesoscale and Nanoscale Physics
Materials Science
Combining magnetometry with optical spectroscopy has uncovered novel quantum phenomena and is emerging as a platform for quantum information science. Yet, the theory of magnetic response of excitons, correlated electron-hole pairs in semiconductors, remains incomplete due to insufficient treatment of electron-hole interaction and topological effects. In biased bilayer graphene, for instance, theoretical predictions of valley g-factor for p-excitons deviate from experiment by nearly an order of magnitude. Here, we develop a quantum theory of exciton orbital magnetic moment that reveals several conceptually new terms absent in prior theories, including an unforeseen contribution from exciton band quantum geometry. Our ab initio calculations yield results in excellent agreement with measurements, establishing the importance of a full theory including interaction and topological effects for the magnetic response of excitons.
title Quantum Theory of Exciton Magnetic Moment: Interaction and Topological Effects
topic Mesoscale and Nanoscale Physics
Materials Science
url https://arxiv.org/abs/2509.07284