Ritu Nehra scite author profile

We study nonlocal transport in a two-leg Kitaev ladder connected to two normal metals. The coupling between the two legs of the ladder when the legs are maintained at a (large) superconducting phase difference, results in the creation of subgap Andreev states. These states in turn are responsible for the enhancement of crossed Andreev reflection. We find that tuning the different parameters of the system suitably leads to enhancement of crossed Andreev reflection signalled by transconductance acquiring the most negative value possible. Furthermore, subgap states cause oscillations of the transconductance as a function of various system parameters such as chemical potential and ladder length, which are seen to be a consequence of Fabry-Pérot resonance. * abhirams@uohyd.ac.in

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Many-body entanglement in a topological chiral ladder

Nehra

Bhakuni

Gangadharaiah

et al. 2018

Phys. Rev. B

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We find that the topological phase transition in a chiral ladder is characterized by dramatic signatures in many body entanglement entropy between the legs, close to half-filling. The value of entanglement entropy for various fillings close to half-filling is identical, at the critical point, but splays out on either side, thus showing a sharp signature at the transition point. A second signature is provided by the change in entanglement entropy when a particle is added (or subtracted) from half-filling which turns out to be exactly − log 2 in the trivial phase, but zero in the topological phase. A microscopic understanding of tendencies to form singlets along the rungs in the trivial phase, and along the diagonals in the topological phase, is afforded by a study of concurrence. At the topological phase transition the magnitude of the derivative of the average concurrence of all the rungs shows a sharp peak. Also, at the critical point, the average concurrence is the same for various fillings close to half-filling, but splays out on either side, just like entanglement entropy. arXiv:1803.00569v1 [cond-mat.mes-hall]

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Drive-induced many-body localization and coherent destruction of Stark many-body localization

2020

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We study the phenomenon of many-body localization (MBL) in an interacting system subjected to a combined DC as well as square wave AC electric field. First, the condition for the dynamical localization, coherent destruction of Wannier-Stark localization and super Bloch oscillations in the non-interacting limit, are obtained semi-classically. In the presence of interactions (and a confining/disordered potential), a static field alone leads to "Stark many-body localization", for sufficiently large field strengths. We find that in the presence of an additional high-frequency AC field, there are two ways of maintaining the MBL intact: either by resonant drive where the ratio of amplitude to the frequency of the drive (A/ω) is tuned at the dynamical localization point of the non-interacting limit, or by off-resonant drive. Remarkably, resonant drive with A/ω tuned away from the dynamical localization point leads to a coherent destruction of Stark-MBL. Moreover, a pure (high-frequency) AC field can also give rise to the MBL phase if A/ω is tuned at the dynamical localization point of the zero dc field problem.

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Topology of multipartite non-Hermitian one-dimensional systems

Nehra

Roy

2022

Phys. Rev. B

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Flat bands and entanglement in the Kitaev ladder

Nehra

Bhakuni

Ramachandran

et al. 2020

Phys. Rev. Research

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We report the existence of flat bands in a p-wave superconducting Kitaev ladder. We identify two sets of parameters for which the Kitaev ladder sustains flat bands. These flat bands are accompanied by highly localized eigenstates known as compact localized states. Invoking a Bogoliubov transformation, the Kitaev ladder can be mapped into an interlinked cross-stitch lattice. The mapping helps to reveal the compactness of the eigenstates each of which covers only two unit cells of the interlinked cross-stitch lattice. The Kitaev Hamiltonian undergoes a topological-to-trivial phase transition when certain parameters are fine-tuned. Correlation matrix techniques allow us to compute entanglement entropy of the many-body eigenstates. The study of entanglement entropy affords fresh insight into the topological phase transitions in the model. Sharp features in entanglement entropy when bands cross indicate a deep underlying relationship between entanglement entropy and dispersion.

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Ritu Nehra

Enhancement of crossed Andreev reflection in a Kitaev ladder connected to normal metal leads

Many-body entanglement in a topological chiral ladder

Drive-induced many-body localization and coherent destruction of Stark many-body localization

Topology of multipartite non-Hermitian one-dimensional systems

Flat bands and entanglement in the Kitaev ladder

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