Dynamical Properties of Quantum Hall Edge States
arXiv:cond-mat/9506055 · doi:10.1103/PhysRevB.52.R8676
Abstract
We consider the dynamical properties of simple edge states in integer ($ν= 1$) and fractional ($ ν= 1/2m+1$) quantum Hall (QH) liquids. The influence of a time-dependent local perturbation on the ground state is investigated. It is shown that the orthogonality catastrophe occurs for the initial and final state overlap $|<i|f>| \sim L^{-{1\over{2ν}}({δ\overÏ})^2}$ with the phase shift $δ$. The transition probability for the x-ray problem is also found with the index, dependent on $ν$. Optical experiments that measure the x-ray response of the QH edge are discussed. We also consider electrons tunneling from one dimensional Fermi liquid into a QH fluid. It is argued that for any filling fraction the tunneling from a Fermi liquid to the QH edge is suppressed at low temperatures and we find the nonlinear $I-V$ characteristics $I\sim V^{1/ν}$.
12 pages. Algebraic error in the tunneling exponent calculation in the last part of the paper is corrected. The orthogonality catastrophe and x-ray calculations are not affected by this error