Ady Stern, Iddo Ussishkin
Published 1997-09-18Version 1
We consider Coulomb drag between two layers of two-dimensional electron gases subject to a strong magnetic field, with the Landau level filling factor in each layer being 1/2. We find $\rho_D$ to be very large, as compared to the zero magnetic field case. We attribute this enhancement to the slow decay of density fluctuations in a strong magnetic field. For a clean system, the linear $q$-dependence of the longitudinal conductivity, characteristic of the $\nu=1/2$ state, leads a unique temperature dependence---$\rd \propto T^{4/3}$. Within a semiclassical approximation, disorder leads to a decrease of the transresistivity as compared with the clean case, and a temperature dependence of $T^2\log T$ at low temperatures.
Comments: RevTeX, 8 pages, 1 figure. This work discusses the role of disorder, which was not discussed in our cond-mat/9701135. To appear in Physica E, in the proceedings of the conference on Novel Physics in Low-Dimensional Electron Systems, Dresden 1997
Journal: Physica E 1 (1997) 176
Drag viscosity of metals and its connection to Coulomb drag
Giant Fluctuations of Coulomb Drag in a Bilayer System
Coulomb drag in mesoscopic rings
