Nonminimal couplings in the Dirac equation generate effective Rashba Hamiltonians from both electric and magnetic fields in 1D rings, enabling exact energy levels, Aharonov-Anandan phases, persistent spin currents, and order-of-magnitude bounds on the couplings g1 and g2.
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In a superconducting analogue of a black hole horizon, decoherence induced by Andreev reflection at weak coupling reemerges as coherence at stronger coupling via resonant tunneling through Andreev bound states.
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Geometric Phases and Persistent Spin Currents from nonminimal couplings
Nonminimal couplings in the Dirac equation generate effective Rashba Hamiltonians from both electric and magnetic fields in 1D rings, enabling exact energy levels, Aharonov-Anandan phases, persistent spin currents, and order-of-magnitude bounds on the couplings g1 and g2.
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Decoherence and the Reemergence of Coherence From a Superconducting "Horizon''
In a superconducting analogue of a black hole horizon, decoherence induced by Andreev reflection at weak coupling reemerges as coherence at stronger coupling via resonant tunneling through Andreev bound states.