Geometric spin–orbit coupling and chirality-induced spin selectivity
Atsuo Shitade, Emi Minamitani
Abstract
Abstract We report a new type of spin–orbit coupling (SOC) called geometric SOC. Starting from the relativistic theory in curved space, we derive an effective nonrelativistic Hamiltonian in a generic curve embedded into flat three dimensions. The geometric SOC is O ( m −1 ), in which m is the electron mass, and hence much larger than the conventional SOC of O ( m −2 ). The energy scale is estimated to be a hundred meV for a nanoscale helix. We calculate the current-induced spin polarization in a coupled-helix model as a representative of the chirality-induced spin selectivity. We find that it depends on the chirality of the helix and is of the order of 0.01 ℏ per nm when a charge current of 1 μ A is applied.
Topics & Concepts
PhysicsHamiltonian (control theory)Coupling (piping)Polarization (electrochemistry)Spin (aerodynamics)ElectronNanoscopic scaleCondensed matter physicsQuantum mechanicsSpin polarizationChirality (physics)Geometric phaseCharge (physics)Atomic physicsEnergy (signal processing)Scale (ratio)Order (exchange)Quantum electrodynamicsCurrent (fluid)Atomic and Molecular PhysicsPhotocathodes and Microchannel PlatesQuantum and Classical Electrodynamics