Controlling particle-hole symmetry of fractional quantum hall states in trilayer graphene

Simrandeep Kaur, Kenji Watanabe, Takashi Taniguchi, Unmesh Ghorai, Rajdeep Sensarma, Aveek Bid

Published 2024-11-28Version 1

We present a detailed experimental study of the particle-hole symmetry (PHS) of the Fractional Quantum Hall (FQH) states about half filling in a multiband system. Specifically, we focus on the lowest Landau level of the monolayer-like band of Bernal stacked trilayer graphene (TLG). In pristine TLG, the excitation energy gaps, Land\'e g-factor, effective mass, and disorder broadening of the FQH states are identical to their hole-conjugate counterpart. This precise PH symmetry stems from the lattice mirror symmetry that precludes Landau-level mixing. Introducing a non-zero displacement field \(D\) disrupts this mirror symmetry, facilitating the hybridization between the \(LL_{M}^{0}\) monolayer-like and \(LL_{B}^{2}\) bilayer-like Landau levels. This band hybridization eventually leads to a violation of the PHS of the FQH states. We find the one-third and two-fifth FQH states to be more robust against Landau level mixing than their hole-conjugate states, which agrees with theoretical predictions [Phys. Rev. Lett. \textbf{113}, 086401 (2014)]. The Landau level mixing parameter $\kappa$ is found to increase sharply with $D$. We stress that the PHS breaking in TLG is of extrinsic origin and differs from the intrinsic, interaction-driven symmetry breaking observed in the lowest Landau levels of single-layer and bilayer graphene. Our research identifies an external factor that can manipulate the PHS in FQH states. Further probing this modulation may help experimentally differentiate between the composite fermion model and the Dirac composite fermion model [Phys. Rev. X \textbf{5}, 031027 (2015)].