High Magnetic Field Microwave Conductivity of 2D Electrons in an Array of Antidots
arXiv:cond-mat/0103127 · doi:10.1103/PhysRevB.65.121305
Abstract
We measure the high magnetic field ($B$) microwave conductivity, Re$Ï_{xx}$, of a high mobility 2D electron system containing an antidot array. Re$Ï_{xx}$ vs frequency ($f$) increases strongly in the regime of the fractional quantum Hall effect series, with Landau filling $1/3<ν<2/3$. At microwave $f$, Re$Ï_{xx}$ vs $B$ exhibits a broad peak centered around $ν=1/2$. On the peak, the 10 GHz Re$Ï_{xx}$ can exceed its dc-limit value by a factor of 5. This enhanced microwave conductivity is unobservable for temperature $T \gtrsim 0.5$ K, and grows more pronounced as $T$ is decreased. The effect may be due to excitations supported by the antidot edges, but different from the well-known edge magnetoplasmons.
4 pages, 3 figures, revtex4