Nonminimal spin-orbit coupling deforms angular-momentum branches in a quantum ring, producing distinct signatures in thermodynamic functions and thermomechanical instabilities enhanced by Fermi statistics, with a phenomenological model yielding anomalous thermal contraction.
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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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Thermodynamics and emergent thermomechanical response of a quantum ring with nonminimal spin--orbit coupling
Nonminimal spin-orbit coupling deforms angular-momentum branches in a quantum ring, producing distinct signatures in thermodynamic functions and thermomechanical instabilities enhanced by Fermi statistics, with a phenomenological model yielding anomalous thermal contraction.
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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.