Excitonic Tonks-Girardeau and charge-density wave phases in monolayer 
semiconductors

Ołdziejewski, Rafał; Chiocchetta, Alessio; Knörzer, Johannes; Schmidt, Richard

doi:10.1103/PhysRevB.106.L081412

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Excitonic Tonks-Girardeau and charge-density wave phases in monolayer semiconductors

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Ołdziejewski, Rafał
Theory, Max Planck Institute of Quantum Optics, Max Planck Society;
MCQST - Munich Center for Quantum Science and Technology, External Organizations;

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Knörzer, Johannes
Theory, Max Planck Institute of Quantum Optics, Max Planck Society;
MCQST - Munich Center for Quantum Science and Technology, External Organizations;

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Schmidt, Richard
Theory, Max Planck Institute of Quantum Optics, Max Planck Society;
MCQST - Munich Center for Quantum Science and Technology, External Organizations;

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Ołdziejewski, R., Chiocchetta, A., Knörzer, J., & Schmidt, R. (2022). Excitonic Tonks-Girardeau and charge-density wave phases in monolayer semiconductors. Physical Review B, 106: L081412. doi:10.1103/PhysRevB.106.L081412.

Cite as: https://hdl.handle.net/21.11116/0000-0009-11D3-5

Abstract

Excitons in two-dimensional semiconductors provide a novel platform for fundamental studies of many-body interactions. In particular, dipolar interactions between spatially indirect excitons may give rise to strongly correlated phases of matter that so far have been out of reach of experiments. Here, we show that excitonic few-body systems in atomically thin transition-metal dichalcogenides undergo a crossover from a Tonks-Girardeau to a charge-density-wave regime. To this end, we take into account realistic system parameters and predict the effective exciton-exciton interaction potential. We find that the pair correlation function contains key signatures of the many-body crossover already at small exciton numbers and show that photoluminescence spectra provide readily accessible experimental fingerprints of these strongly correlated quantum many-body states.