A. R. Goñi, P. Giudici, F. A. Reboredo, C. R. Proetto, C. Thomsen, K. Eberl, M. Hauser
Published 2004-04-06Version 1
Density-functional calculations using an exact exchange potential for a two-dimensional electron gas (2DEG) formed in a GaAs single quantum well predict the existence of a spin-polarized phase, when an excited subband becomes slightly populated. Direct experimental evidence is obtained from low temperature and low excitation-power photoluminescence (PL) spectra which display the sudden appearance of a sharp emission peak below the energy of the optical transition from the first excited electron subband upon its occupation. The behavior of this PL feature in magnetic fields applied in-plane as well as perpendicular to the 2DEG indicate the formation of spin-polarized domains in the excited subband with in-plane magnetization. For it speaks also the strong enhancement of exchange-vertex corrections observed in inelastic light scattering spectra by spin-density excitations of a slightly occupied first-excited subband.
Comments: one tex file and four figures
Transport relaxation rate of a two-dimensional electron gas: Surface acoustic-phonon contribution
Dynamics of Spin Relaxation near the Edge of Two-Dimensional Electron Gas
Variational Monte-Carlo calculation of the nematic state of the two-dimensional electron gas in a magnetic field
