Theoretical Comparison of Rashba Spin-Orbit Coupling in Digitally, Discretely, and Continuously Alloyed Nanostructures

TL;DR

This paper compares Rashba spin-orbit coupling in triangular quantum wells with continuous, discrete, and digital alloy profiles, revealing significant differences especially in digital alloys, with implications for spintronic device design.

Contribution

It provides a detailed theoretical comparison of Rashba spin-orbit interaction across different alloying profiles, highlighting the unique behavior of digitally-alloyed quantum wells.

Findings

Digital alloying significantly alters Rashba coupling compared to other profiles.

Interface contribution is negligible in digital alloys but dominant in continuous and discrete alloys.

Electric field contribution is similar across all alloying methods, especially at higher doping levels.

Abstract

Although most theoretical calculations of quantum wells with non-square profiles assume that material composition is varied continuously, it is more common in experiment to grow digital alloys. We compare the Rashba spin-orbit interaction of triangular wells using continuous, discrete, and digital alloying profiles in (001)-grown triangular InSb/Al_f(z)In_(1-f(z))Sb, finding a very large difference between digital alloying and the others, including a sign change in the Rashba spin-orbit coupling. We find that the interface contribution to the Rashba spin-orbit coupling is much larger in the continuously- and discretely-alloyed triangular quantum wells than in the digitally-alloyed triangular wells, in which it is almost completely absent. The electric field contribution, however, is quite similar in all three systems. Due to a much stronger doping dependence in all three systems, the electric field contribution dominates at higher dopings, although the very large offset due to the near absence of interface contribution in digitally-alloyed wells persists.