Scattering Hypervolume of Fermions in Two Dimensions
Abstract
We define the three-body scattering hypervolume DF for identical spin-polarized fermions in two dimensions, by considering the wave function of three such fermions colliding at zero energy and zero orbital angular momentum. We derive the asymptotic expansions of such a wave function when three fermions are far apart or one pair and the third fermion are far apart, and DF appears in the coefficients of such expansions. For weak interaction potentials, we derive an approximate formula of DF by using the Born expansion. We then study the shift of energy of three such fermions in a large periodic area due to DF. This shift is proportional to DF times the square of the area of the triangle formed by the momenta of the fermions. We also calculate the shifts of energy and of pressure of spin-polarized two-dimensional Fermi gases due to a nonzero DF and the three-body recombination rate of spin-polarized ultracold atomic Fermi gases in two dimensions.
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