Derives a refraction law for vortices at tilted SN interfaces, confirmed by proximity-effect simulations that also reveal low-mass trapping and viscosity-driven displacements under transport current.
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4 Pith papers cite this work. Polarity classification is still indexing.
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UNVERDICTED 4representative citing papers
Introduces spinor pairing orders with half-integer monopole charges from odd Chern number differences between paired Fermi surfaces, shown in tight-binding models with single gap nodes and fractional Mermin-Ho relations.
In the supersymmetric gapped phase of an interacting Majorana chain, the lowest excitations are soliton-antisoliton pairs, each binding a localized Majorana mode that together form a nonlocal Dirac fermion distinguishing even and odd fermion parity states.
Numerical study demonstrates controlled transport of Z4 parafermion edge states in a ladder model and quantifies the adiabatic speed limit under realistic conditions.
citing papers explorer
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Vortex Refraction at Tilted Superconductor-Normal Metal Interfaces
Derives a refraction law for vortices at tilted SN interfaces, confirmed by proximity-effect simulations that also reveal low-mass trapping and viscosity-driven displacements under transport current.
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Berry Phase Enforced Spinor Pairing Order
Introduces spinor pairing orders with half-integer monopole charges from odd Chern number differences between paired Fermi surfaces, shown in tight-binding models with single gap nodes and fractional Mermin-Ho relations.
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Soliton-antisoliton pairs in the supersymmetric gapped phase of an interacting Majorana chain
In the supersymmetric gapped phase of an interacting Majorana chain, the lowest excitations are soliton-antisoliton pairs, each binding a localized Majorana mode that together form a nonlocal Dirac fermion distinguishing even and odd fermion parity states.
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Shuttling of $\mathbb{Z}_4$ parafermions in an electronic ladder model
Numerical study demonstrates controlled transport of Z4 parafermion edge states in a ladder model and quantifies the adiabatic speed limit under realistic conditions.