Your search keyword '"Michael M. Fogler"' showing total 3 results

1. Effects of interactions and disorder on the compressibility of two-dimensional electron and hole systems

Author

Michael M. Fogler, A. K. Savchenko, Michelle Y. Simmons, David A. Ritchie, Giles Allison, S. S. Safonov, and E. A. Galaktionov

Subjects

Materials science, Condensed matter physics, business.industry, Electron hole, Electron, Flory–Huggins solution theory, Condensed Matter Physics, Capacitance, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Nonlinear system, Semiconductor, Compressibility, Metal–insulator transition, business

Abstract

The compressibility Χ of dilute two-dimensional electron and hole gases in GaAs semiconductor structures has been studied in the ranges of the interaction parameter r s = 1-2.5 and r s = 10-30 for the electron and hole system, respectively. Nonmonotonic dependence of Χ -1 with an upturn at low carrier densities is observed. Despite the large difference in r s the behavior of Χ -1 in both systems can be accurately described by the theory of nonlinear screening of disorder by the carriers.

Published

2006

2. Dynamics of disordered quantum Hall crystals

Author

Michael M. Fogler

Subjects

Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed matter physics, FOS: Physical sciences, Charge density, Landau quantization, Electron, Quantum Hall effect, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Wigner crystal, Magnetic field, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), Quasiparticle, Charge density wave

Abstract

Charge density waves are thought to be common in two-dimensional electron systems in quantizing magnetic fields. Such phases are formed by the quasiparticles of the topmost occupied Landau level when it is partially filled. One class of charge density wave phases can be described as electron solids. In weak magnetic fields (at high Landau levels) solids with many particles per unit cell - bubble phases - predominate. In strong magnetic fields (at the lowest Landau level) only crystals with one particle per unit cell - Wigner crystals - can form. Experimental identification of these phases is facilitated by the fact that even a weak disorder influences their dc and ac magnetotransport in a very specific way. In the ac domain, a range of frequencies appears where the electromagnetic response is dominated by magnetophonon collective modes. The effect of disorder is to localize the collective modes and to create an inhomogeneously broadened absorption line, the pinning mode. In recent microwave experiments pinning modes have been discovered both at the lowest and at high Landau levels. We present the theory of the pinning mode for a classical two-dimensional electron crystal collectively pinned by weak impurities. We show that long-range Coulomb interaction causes a dramatic line narrowing, in qualitative agreement with the experiments., Comment: 6 pages, 3 figures. To be presented at EP2DS-15, Nara, Japan. One typo corrected

Published

2004

3. Localization length at the conductivity minima of the quantum Hall effect

Author

Boris I Shklovskii, A. Yu. Dobin, and Michael M. Fogler

Subjects

Physics, Condensed matter physics, Gyroradius, Quantum Hall effect, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Magnetic field, Weak localization, Maxima and minima, Quantum spin Hall effect, Quantum mechanics, Exponent, Quantum

Abstract

The quantum localization is known to be responsible for the deep conductivity minima of the quantum Hall effect. In this paper we calculate the localization length ξ as a function of magnetic field B at such minima for several models of disorder (“white-noise”, short-range, and long-range random potentials). We find that ξ∝B−α with the exponent α between one and 10 3 , depending on the model. In particular, for the “white-noise” random potential ξ roughly coincides with the classical cyclotron radius. Our results are in agreement with available experimental data.

Published

1997