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Nonbosonic Moiré Excitons

T. S. Huang, Peter Lunts, Mohammad Hafezi

2024Physical Review Letters12 citationsDOIOpen Access PDF

Abstract

Optical excitations in moiré transition metal dichalcogenide bilayers lead to the creation of excitons, as electron-hole bound states, that are generically considered within a Bose-Hubbard framework. Here, we demonstrate that these composite particles obey an angular momentum commutation relation that is generally nonbosonic. This emergent spin description of excitons indicates a limitation to their occupancy on each site, which is substantial in the weak electron-hole binding regime. The effective exciton theory is accordingly a spin Hamiltonian, which further becomes a Hubbard model of emergent bosons subject to an occupancy constraint after a Holstein-Primakoff transformation. We apply our theory to three commonly studied bilayers (MoSe_{2}/WSe_{2}, WSe_{2}/WS_{2}, and WSe_{2}/MoS_{2}) and show that in the relevant parameter regimes their allowed occupancies never exceed three excitons. Our systematic theory provides guidelines for future research on the many-body physics of moiré excitons.

Topics & Concepts

ExcitonPhysicsHamiltonian (control theory)Condensed matter physicsBosonHubbard modelMany-body theoryQuantum mechanicsSpin (aerodynamics)Angular momentumElectronMathematical optimizationMathematicsThermodynamicsSuperconductivity2D Materials and ApplicationsStrong Light-Matter InteractionsPerovskite Materials and Applications
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