Photoluminescence from two-dimensional electrons in a magnetic field

An analysis of light scattering from a two-dimensional electron gas (2DEG) subject to a weak periodic magnetic modulation of strength B m and to a perpendicular uniform magnetic field B of arbitrary strength is presented. Raman spectra are calculated for (i) electron inter-Landau-level transitions,

We present the first measurements concerning the photon drag effect in a two-dimensional electron gas based on intersubband transitions in high magnetic fields. It is shown that the excitation mechanism of the drag voltage in a magnetic field differs obviously from the case of zero magnetic field. T

We consider the behavior of a slowly moving classical point particle in a magnetic field in two dimensions, and show that, although energy conservation would permit the particle to escape to infinity, it in fact does not escape but is permanently trapped in the field. For any given magnetic field, t

We theoretically study the electron-electron scattering rate τ -1 ee for electrons in a twodimensional electron gas with a perpendicular magnetic field, within the GW and plasmonpole approximations, as functions of temperature T , impurity scattering rate and magnetic field B. The τ -1 ee increases