The nonlinear Schr\"odinger equation (NLSE) is a rich and versatile model, which in one spatial dimension has stationary solutions similar to those of the linear Schr\"odinger equation as well as more exotic solutions such as solitary waves and quantum droplets. We present a unified theory of the NLSE, showing that all stationary solutions of the cubic-quintic NLSE can be classified according to a single number called the cross-ratio. Any two solutions with the same cross-ratio can be converted into one another using a conformal transformation, and the same also holds true for traveling wave solutions. In this way we demonstrate a conformal duality between solutions of cubic-quintic NLSEs and lower-order NLSEs. The same analysis can be applied to the Newtonian dynamics of classical particles with polynomial potentials. Our framework provides a deeper understanding of the connections between the physics of the NLSE and the mathematics of algebraic curves and conformal symmetry.
Comment: 12 pages, 2 figures