Group theoretical methods and k · p theory are combined to determine spin-dependent contributions to the effective conduction band Hamiltonian. To obtain the constants in the effective Hamiltonian, in general all invariants of the Hamiltonian have to be determined. Hence, we present a systematic approach to keep track of all possible invariants and apply it to the k · p Hamiltonian of crystals with zincblende symmetry, in order to find all possible contributions to effective quantities such as effective mass, g-factor and Dresselhaus constant. Additional spin-dependent contributions to the effective Hamiltonian arise in the presence of strain. In particular, with regard to the constants C 3 and D which describe spin-splitting linear in the components of k and ε, considering all possible terms allowed by symmetry is crucial.
Recent experiments have shown the potential of surface acoustic waves as a mean for transporting charge and spin in quantum wells. In particular, they have proven highly effective for the coherent transport of spin-polarized wave packets, suggesting their potential in spintronics applications. Motivated by these experimental observations, we have theoretically studied the spin and charge dynamics in a quantum well under surface acoustic waves. We show that the dynamics acquires a simple and transparent form in a reference frame co-moving with the surface acoustic wave. Our results, e.g., the calculated spin relaxation and precession lengths, are in excellent agreement with recent experimental observations.
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