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Main Authors: Nguyen, Thi-Hau, Do, Thi-Hong-Hai, Phan, Van-Nham
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.07294
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author Nguyen, Thi-Hau
Do, Thi-Hong-Hai
Phan, Van-Nham
author_facet Nguyen, Thi-Hau
Do, Thi-Hong-Hai
Phan, Van-Nham
contents The interplay of the excitoniclike polariton, polariton, and photoniclike polariton coherent states in mass-imbalanced electron-hole systems within optical microcavities is theoretically examined. Utilizing the unrestricted Hartree-Fock approximation, we derive a set of self-consistent equations that evaluate the excitonic and photonic order parameters in a two-band electronic model, accounting equally for both electron-hole Coulomb attraction and light-matter coupling. Analyzing the competition among these condensate order parameters reveals a complex phase structure of coherent states in the ground state. As the mass imbalance is reduced, we observe a transition from a normal disordered electron-hole-photon system to excitoniclike, polariton, and ultimately photoniclike polariton condensation states. The distinct features of these robust condensates can be identified in the momentum distribution of the electron-hole pair amplitude and the photonic density, as well as in the wave-number-resolved photoemission spectra of electrons, holes, and photons. Increasing the excitation density further expands the range of condensation states. Additionally, lowering the mass imbalance leads to the emergence of quantum coherent bound states prior to the formation of robust condensates, which are evidenced by the static and dynamical excitonic and photonic susceptibility functions.
format Preprint
id arxiv_https___arxiv_org_abs_2512_07294
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Quantum coherent states of mass-imbalanced electron-hole system within optical microcavities
Nguyen, Thi-Hau
Do, Thi-Hong-Hai
Phan, Van-Nham
Strongly Correlated Electrons
The interplay of the excitoniclike polariton, polariton, and photoniclike polariton coherent states in mass-imbalanced electron-hole systems within optical microcavities is theoretically examined. Utilizing the unrestricted Hartree-Fock approximation, we derive a set of self-consistent equations that evaluate the excitonic and photonic order parameters in a two-band electronic model, accounting equally for both electron-hole Coulomb attraction and light-matter coupling. Analyzing the competition among these condensate order parameters reveals a complex phase structure of coherent states in the ground state. As the mass imbalance is reduced, we observe a transition from a normal disordered electron-hole-photon system to excitoniclike, polariton, and ultimately photoniclike polariton condensation states. The distinct features of these robust condensates can be identified in the momentum distribution of the electron-hole pair amplitude and the photonic density, as well as in the wave-number-resolved photoemission spectra of electrons, holes, and photons. Increasing the excitation density further expands the range of condensation states. Additionally, lowering the mass imbalance leads to the emergence of quantum coherent bound states prior to the formation of robust condensates, which are evidenced by the static and dynamical excitonic and photonic susceptibility functions.
title Quantum coherent states of mass-imbalanced electron-hole system within optical microcavities
topic Strongly Correlated Electrons
url https://arxiv.org/abs/2512.07294