Spin-orbit split two-dimensional electron gas with tunable Rashba and Fermi energy

We demonstrate that it is possible to tune the Rashba energy, introduced by a strong spin-orbit splitting, and the Fermi energy in a two-dimensional electron gas by a controlled change of stoichiometry in an artificial surface alloy. In the BixPb1-x/Ag(111) surface alloy, the spin-orbit interaction maintains a dramatic influence on the band dispersion for arbitrary Bi concentration x, as is shown by angle-resolved photoelectron spectroscopy. The Rashba energy E-R and the Fermi energy E-F can be tuned to achieve values larger than one for the ratio E-R/E-F, which opens up the possibility for observing phenomena, such as corrections to the Fermi liquid or a superconducting state. Relativistic first-principles calculations explain the experimental findings.

Spin-orbit split two-dimensional electron gas with tunable Rashba and Fermi energy

Field-induced ultrafast modulation of Rashba coupling at room temperature in ferroelectric alpha-GeTe(111)

Quantum interference effects of out-of-plane confinement on two-dimensional electron systems in oxides

Crystal electric field excitations in the quantum spin liquid candidate NaErS2

Crystal electric field excitations in the quantum spin liquid candidate NaErS2

Quantum interference effects of out-of-plane confinement on two-dimensional electron systems in oxides

Field-induced ultrafast modulation of Rashba coupling at room temperature in ferroelectric alpha-GeTe(111)