Quantum Theory of Quantum-Hall Smectics
arXiv:cond-mat/9907278 · doi:10.1103/PhysRevB.61.5724
Abstract
We propose a quantum stripe (smectic) coupled-Luttinger-liquid model for the anisotropic states which occur in two-dimensional electron systems with high-index partial Landau level filling, $ν^{*} = ν- \lbrackν\rbrack$. Perturbative renormalization group calculations establish that interaction terms neglected in this model are relevant - probably driving the system into an anisotropic Wigner crystal---but for $0.4 \lesssim ν^{*} \lesssim 0.6$ only below temperatures which are outside of the experimentally accessible range. We argue that the Hall conductance of the ground state flows toward $\lbrackν\rbrack e^{2}/h$ and $(\lbrackν\rbrack + 1) e^{2}/h$ respectively, on the low and high filling factor sides of this range, consistent with recent observations. A semiclassical theory of smectic state transport properties, which incorporates Luttinger liquid effects in the evaluation of scattering amplitudes, accounts for the magnitude of the dissipative resistivities at $ν^{*}=1/2$, for their $ν^{*}$-dependence, and for the observation of non-linearities of opposite sign in easy and hard direction resistivities.
12 pages, 7 figures included, submitted to Phys. Rev. B