Bilinear approach to the quasi-periodic wave solutions of supersymmetric equations in superspace

TL;DR

This paper introduces a straightforward method for constructing quasi-periodic wave solutions of supersymmetric equations in superspace, analyzing their properties, and establishing their relation to soliton solutions, with applications to various supersymmetric equations.

Contribution

The paper presents a new explicit bilinear method for constructing quasi-periodic solutions of supersymmetric equations in superspace, including analysis of their properties and relation to solitons.

Findings

Quasi-periodic solutions can be explicitly constructed from bilinear forms.

Soliton solutions are limiting cases of quasi-periodic solutions under small amplitude limits.

Grassmann variables influence the structure and behavior of quasi-periodic waves.

Abstract

We devise a lucid and straightforward way for explicitly constructing quasi-periodic wave solutions (also called multi-periodic wave solutions) of supersymmetric equations in superspace $\mathbb{R}_\Lambda^{2,1}$ over two-dimensional Grassmann algebra $G_1(\sigma)$. Once a nonlinear equation is written in a bilinear form, its quasi-periodic wave solutions can be directly obtained by using a formula. Moreover, properties of these solutions are investigated in detail by analyzing their structures, plots and asymptotic behaviors. The relations between the quasi-periodic wave solutions and soliton solutions are rigorously established. It is shown that the soliton solutions can be obtained only as limiting cases of the quasi-periodic wave solutions under small amplitude limits in superspace $\mathbb{R}_\Lambda^{2,1}$. We find that, in contrast to the purely bosonic case, there is an interesting influencing band occurred among the quasi-periodic waves under the presence of the Grassmann variable. The quasi-periodic waves are symmetric about the band but collapse along with the band. Furthermore, the amplitudes of the quasi-periodic waves increase as the waves move away from the band. The efficiency of our proposed method can be demonstrated on a class variety of supersymmetric equations such as those considered in this paper, $\mathcal{N}=1$ supersymmetric KdV, Sawada-Kotera-Ramani and Ito's equations, as well as $\mathcal{N}=2$ supersymmetric KdV equation.