Josephson Diode Effect for a Kitaev Ladder System
Abstract
We study the Josephson diode effect realized purely by geometry in a Kitaev-ladder Josephson junction composed of two parallel spinless p-wave chains coupled by an interleg hopping t. The junction is governed by two phases: the superconducting phase difference across the weak link, θ, and the leg-to-leg phase difference, φ. For φ \0, π\ (mod 2π), time-reversal symmetry is broken, and the absence of leg-exchange symmetry leads to a breakdown of the antisymmetry of the current-phase relation, yielding nonreciprocal Josephson transport without magnetic fields or spin-orbit coupling. By resolving transport into bonding and antibonding channels defined by t, it is shown that the leg phase acts as an effective phase shift for interband (p/p-) tunneling, whereas the same-band (p/p) contribution remains unshifted. These channels arise at different perturbative orders and, together with the 4π-periodic Majorana channel that emerges near the topological transition, interfere to produce a pronounced diode response. The class-D Pfaffian invariant identifies the parameter regime where the ladder hosts Majorana zero modes. Bogoliubov-de Gennes calculations reveal a dome-like dependence of the diode efficiency η on t: η 0 for t 0 and for large t, with a maximum at intermediate coupling that is tunable by φ. The present results establish a field-free, geometry-based route to superconducting rectification in one-dimensional topological systems and specify symmetry and topology conditions for optimizing the effect in ladder and network devices.
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