Theory of Rashba splitting in quantum-well states
Abstract
We present a theory pertaining to the asymptotic behavior of Rashba energy splitting in a quantum-well state (QWS). First, unlike previous studies, we derive k-linear Rashba term from a first-principles Hamiltonian in a physically convincing manner. The k-dependent in-plane intrinsic magnetic-field term originates from the spin--orbit interaction and hybridized s-pz orbital, whereas a steep nucleus potential realizes the linearity for the k of the effective magnetic field. Next, we analyze the Rashba effect of a QWS using a one-dimensional tight-binding model developed based on the bottom-up approach that is aforementioned. The Rashba-splitting behavior of this system is captured from the density at the interface. The density can be expressed analytically as a function of the monolayer number and well depth. Finally, we apply our formula to the QWS of a few-monolayers Ag on an Au(111) surface to validate the theory based on a realistic system. Our tight-binding analysis qualitatively fits the first-principles result using only two fitting parameters and predicts the optimal condition for achieving a large Rashba splitting.
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