# 科研成果 by Year: 2020

Asymmetry of the geometrical resonances of composite fermions. Phys. Rev. B [Internet]. 2020;101:235301. 访问链接Abstract

. Berry phase in the composite Fermi liquid. Phys. Rev. Research [Internet]. 2020;2:033329. 访问链接Abstract

. 2020

Ji G, Shi J. Asymmetry of the geometrical resonances of composite fermions. Phys. Rev. B [Internet]. 2020;101:235301. 访问链接Abstract

We propose an experiment to test the uniform-Berry-curvature picture of composite fermions. We show that the asymmetry of geometrical resonances observed in a periodically modulated composite fermion system can be explained with the uniform-Berry-curvature picture. Moreover, we show that an alternative way of modulating the system, i.e., modulating the external magnetic field, will induce an asymmetry opposite to that of the usual periodic grating modulation which effectively modulates the Chern-Simons field. The experiment can serve as a critical test of the uniform-Berry-curvature picture and probe the dipole structure of composite fermions proposed by Read.

Ji G, Shi J. Berry phase in the composite Fermi liquid. Phys. Rev. Research [Internet]. 2020;2:033329. 访问链接Abstract

We derive the definition of the Berry phase for the adiabatic transport of a composite fermion (CF) in a half-filled composite Fermi liquid (CFL). It is found to be different from that adopted in previous investigations by Geraedts et al. For the standard CFL wave function, we analytically show that the Berry curvature is uniformly distributed in the momentum space. For the Jain-Kamilla wave function, we numerically show that its Berry curvature has a continuous distribution inside the Fermi sea and vanishes outside. We conclude that the CF with respect to both the microscopic wave functions is not a massless Dirac particle.