Spin Dynamics in the Second Subband of a Quasi Two Dimensional System Studied in a Single Barrier Heterostructure by Time Resolved Kerr Rotation

Abstract

By biasing a single barrier heterostructure with a 500nm-thick GaAs layer as the absorption layer, the spin dynamics for both of the first and second subband near the AlAs barrier are examined. We find that when simultaneously scanning the photon energy of both the probe and pump beams, a sign reversal of the Kerr rotation (KR) takes place as long as the probe photons break away the first subband and probe the second subband. This novel feature, while stemming from the exchange interaction, has been used to unambiguously distinguish the different spin dynamics (T21* and T22*) for the first and second subbands under the different conditions by their KR signs (negative for 1st and positive for 2nd). In the zero magnetic field, by scanning the wavelength towards the short wavelength, T21* decreases in accordance with the D'yakonov-Perel' (DP) spin decoherence mechanism. At 803nm, T22*(450ps) becomes ten times longer than T21*(50ps). However, the value of T22* at 803nm is roughly the same as the value of T21* at 815nm. A new feature has been disclosed at the wavelength of 811nm under the bias of -0.3V (807nm under the bias of -0.6V) that the spin coherence times (T21* and T22*) and the effective g* factors (|g*(E1)| and |g*(E2)|) all display a sudden change, due to the "resonant" spin exchange coupling between two spin opposite bands.