Exact Quantum Solutions of Extraordinary N-body Problems
D. Lynden-Bell, R.M. Lynden-Bell
TL;DR
This paper provides exact solutions to the N-body Schrödinger equation for a class of potentials depending on the sum of squared inter-particle distances, with applications to quantum gases, nuclear models, and astrophysics.
Contribution
It generalizes known wave functions to solve the N-body problem for potentials based on the sum of squared distances, including explicit solutions for specific inverse-distance potentials.
Findings
Explicit N-body solutions for specific potentials.
Degeneracy formulas for different particle types.
Application to white dwarf star modeling.
Abstract
The wave functions of Boson and Fermion gases are known even when the particles have harmonic interactions. Here we generalise these results by solving exactly the N-body Schrodinger equation for potentials V that can be any function of the sum of the squares of the distances of the particles from one another in 3 dimensions. For the harmonic case that function is linear in r^2. Explicit N-body solutions are given when U(r) = -2M \hbar^{-2} V(r) = \zeta r^{-1} - \zeta_2 r^{-2}. Here M is the sum of the masses and r^2 = 1/2 M^{-2} Sigma Sigma m_I m_J ({\bf x}_I - {\bf x}_J)^2. For general U(r) the solution is given in terms of the one or two body problem with potential U(r) in 3 dimensions. The degeneracies of the levels are derived for distinguishable particles, for Bosons of spin zero and for spin 1/2 Fermions. The latter involve significant combinatorial analysis which may have…
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