Probing strong interactions in p-type few-layer WSe$_2$ by density-dependent Landau level crossing

TL;DR

This study reveals strong Coulomb interactions and density-dependent Landau level crossings in p-type few-layer WSe$_2$, demonstrating enhanced g-factors and potential for exploring correlated electronic phenomena like Wigner crystallization.

Contribution

It provides the first transport evidence of density-dependent Landau level crossings and Coulomb interaction effects in p-type few-layer WSe$_2$, highlighting its potential for strongly correlated physics.

Findings

Observation of density-dependent quantum Hall states in WSe$_2$

Enhanced g-factor indicating strong Coulomb interactions

Potential for realizing Wigner crystallization at moderate densities

Abstract

Atomically thin transition metal dichalcogenides (TMDCs) such as MoS$_2$ and WSe$_2$ are emerging as a new platform for exploring many-body effects. Coulomb interactions are markedly enhanced in these materials because of the reduced screening and the large Wigner-Seitz radii. Although many-body excitonic effects in TMDCs have been extensively studied by optical means, not until recently did probing their strongly correlated electronic effects become possible in transport. Here, in p-type few-layer WSe$_2$ we observe highly density-dependent quantum Hall states of {\Gamma} valley holes below 12 T, whose predominant sequences alternate between odd- and even-integers. By tilting the magnetic field to induce Landau level crossings, we show that the strong Coulomb interaction enhances the Zeeman-to-cyclotron energy ratio from 2.67 to 3.55 as the density is reduced from 5.7 to 4.0$\times$10$^{12}$ cm$^{-2}$, giving rise to the even-odd alternation. Unprecedentedly, this indicates a 4.8 times enhancement of the g-factor over its band theory value at a density as high as 4.0$\times$10$^{12}$ cm$^{-2}$. Our findings unambiguously demonstrate that p-type few-layer WSe$_2$ is a superior platform for exploring strongly correlated electronic phenomena, opening a new perspective for realizing the elusive Wigner crystallization at a moderate density.