2019
DOI: 10.1002/adts.201900173
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Analytical Solutions for a Supersymmetric Wave‐Equation for Quasiparticles in a Quantum System

Abstract: Vortices and quasiparticles have been studied for 2D systems over the past decades in relation to the development of technologies in quantum electromagnetics, optics, and quantum computation. Deriving new equations for quasiparticles in quantum systems is therefore a critical part of quantum physics. Recently, a supersymmetric wave equation has been developed which describes quasiparticles and vorticity under the influence of electromagnetic fields which has been studied numerically. The analytical solutions o… Show more

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Cited by 4 publications
(7 citation statements)
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“…Figure shows furthermore the numerical solution of the system given in under a homogeneous magnetic field (where the periodical initial condition in is absent). The vorticity formed under the homogeneous magnetic field (Figure , 3rd row) is more pronounced than under the absence of a magnetic field (Figure , 2nd row) and shares similarities to our previous work . The model suggests therefore that vorticity arises both under the presence and also under absence of a magnetic field, which is well in agreement with literature of forming vorticity without magnetic fields (i.e., hydrodynamic vorticity or in turbulent fluids).…”
Section: Numerical Solutions Of the Supersymmetric Wave‐equationsupporting
confidence: 89%
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“…Figure shows furthermore the numerical solution of the system given in under a homogeneous magnetic field (where the periodical initial condition in is absent). The vorticity formed under the homogeneous magnetic field (Figure , 3rd row) is more pronounced than under the absence of a magnetic field (Figure , 2nd row) and shares similarities to our previous work . The model suggests therefore that vorticity arises both under the presence and also under absence of a magnetic field, which is well in agreement with literature of forming vorticity without magnetic fields (i.e., hydrodynamic vorticity or in turbulent fluids).…”
Section: Numerical Solutions Of the Supersymmetric Wave‐equationsupporting
confidence: 89%
“…In regular Gross–Pitaevskii models the β parameter is related both to the number of particles and their interaction with one another, however in our SWE it defines rather the vortex (quasiparticle) interaction and hence the preferred symmetry the vortices adapt. It follows thus from the data that the β parameter does not affect the number of vortices (see Figure ), but rather affects the amplitude of the wave function, as we have previously established in our work . Most importantly, the β parameter allows vortices to be formed spontaneously, without the use of auxiliary functions or perturbations.…”
Section: Numerical Solutions Of the Supersymmetric Wave‐equationsupporting
confidence: 72%
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