Yuval Oreg, Gil Refael, Felix von Oppen
Published 2010-03-05, updated 2010-06-10Version 2
We show that the combination of spin-orbit coupling with a Zeeman field or strong interactions may lead to the formation of a helical liquid in single-channel quantum wires. In a helical liquid, electrons with opposite velocities have opposite spin precession. We argue that zero-energy Majorana bound states are formed in various situations when the wire is situated in proximity to a conventional s-wave superconductor. This occurs when the external magnetic field, the superconducting gap, or, in particular, the chemical potential vary along the wire. We discuss experimental consequences of the formation of the helical liquid and the Majorana bound states.
Comments: 4+epsilon pages
Intrasubband plasmons in a finite array of quantum wires placed into an external magnetic field
Control of a two-electron quantum ring with an external magnetic field
Spin relaxation in the impurity band of a semiconductor in the external magnetic field
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