# On nonlocal models of Kulish-Sklyanin type and generalized Fourier   transforms

**Authors:** Vladimir S. Gerdjikov

arXiv: 1703.03705 · 2017-03-13

## TL;DR

This paper explores integrable multicomponent nonlinear Schrödinger equations related to symmetric spaces, introduces a generalized Fourier transform via scattering data, and applies it to models of spinor Bose-Einstein condensates.

## Contribution

It develops a framework for solving multicomponent NLS equations using inverse scattering and generalized Fourier transforms, extending previous methods to new symmetric space models.

## Key findings

- Constructed fundamental analytic solutions for the equations.
- Defined minimal scattering data sets that uniquely determine the potential.
- Applied the theory to models of spinor Bose-Einstein condensates.

## Abstract

A special class of multicomponent NLS equations, generalizing the vector NLS and related to the {\bf BD.I}-type symmetric are shown to be integrable through the inverse scattering method (ISM). The corresponding fundamental analytic solutions are constructing thus reducing the inverse scattering problem to a Riemann-Hilbert problem. We introduce the minimal sets of scattering data $\mathfrak{T}$ which determines uniquely the scattering matrix and the potential $Q$ of the Lax operator. The elements of $\mathfrak{T}$ can be viewed as the expansion coefficients of $Q$ over the `squared solutions' that are natural generalizations of the standard exponentials. Thus we demonstrate that the mapping $\mathfrak{T} \to Q$ is a generalized Fourier transform. Special attention is paid to two special representatives of this MNLS with three-component and five components which describe spinor ($F=1$ and $F=2$, respectively) Bose-Einstein condensates.

## Full text

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## References

44 references — full list in the complete paper: https://tomesphere.com/paper/1703.03705/full.md

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Source: https://tomesphere.com/paper/1703.03705