Generalization of the Fermi Pseudopotential

TL;DR

This paper generalizes the Fermi pseudopotential to non-integer dimensions and non-zero energy, providing a singularity-free, versatile tool for quantum physics applications across various dimensions.

Contribution

It introduces a novel generalized Fermi pseudopotential applicable to non-integer dimensions and finite energy, simplifying the coupling constant expression and avoiding singularities.

Findings

Valid for non-integer and integer dimensions

Equivalent to known s-wave pseudopotentials at integer dimensions

Simplifies the energy expression for two cold atoms in a harmonic trap

Abstract

Introduced eighty years ago, the Fermi pseudopotential has been a powerful concept in multiple fields of physics. It replaces the detailed shape of a potential by a delta-function operator multiplied by a parameter giving the strength of the potential. For Cartesian dimensions $d>1$, a regularization operator is necessary to remove singularities in the wave function. In this study, we develop a Fermi pseudopotential generalized to $d$ dimensions (including non-integer) and to non-zero wavenumber, $k$. Our approach has the advantage of circumventing singularities that occur in the wave function at certain integer values of $d$ while being valid arbitrarily close to integer $d$. In the limit of integer dimension, we show that our generalized pseudopotential is equivalent to previously derived $s$-wave pseudopotentials. Our pseudopotential generalizes the operator to non-integer dimension, includes energy ($k$) dependence, and simplifies the dimension-dependent coupling constant expression derived from a Green's function approach. We apply this pseudopotential to the problem of two cold atoms ($k\to0$) in a harmonic trap and extend the energy expression to arbitrary dimension.