【 摘 要 】

Spin relaxation in a quantum Hall ferromagnet, where filling is nu = 1,1/3,1/5, ... , can be considered in terms of spin-wave annihilation/creation processes. Hyperfine coupling with the nuclei of the GaAs matrix provides spin nonconservation in the two-dimensional electron gas and determines spin relaxation in the quantum Hall system. This mechanism competes with spin-orbit coupling channels of spin-wave decay and can even dominate in a low-temperature regime where T is much smaller than the Zeeman gap. In this case the spin-wave relaxation process occurs nonexponentially with time and does not depend on the temperature. The competition of different relaxation channels results in crossovers in the dominant mechanism, leading to nonmonotonic behavior of the characteristic relaxation time with the magnetic field. We predict that the relaxation times should reach maxima at B similar or equal to 18 T in the nu = 1 quantum Hall system and at B similar or equal to 12 T for that of nu = 1/3. We estimate these times as similar to 10-30 mu s and similar to 2-5 mu s, respectively.

【 授权许可】

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