Exact relations for quantum-mechanical few-body and many-body problems with short-range interactions in two and three dimensions

TL;DR

This paper derives exact relations between various observables for quantum particles with short-range interactions in different dimensions, generalizing known results and providing new formulas for energy derivatives and corrections, with applications to few- and many-body problems.

Contribution

It introduces generalized exact relations for quantum systems with short-range interactions, including new formulas for energy derivatives and corrections, applicable to both two- and three-dimensional cases.

Findings

Derived relations between observables for N particles with short-range interactions.

Generalized energy-momentum distribution relations and identified breakdown for Efimov states.

Validated relations through comparisons with numerical simulations and Monte Carlo data.

Abstract

We derive relations between various observables for N particles with zero-range or short-range interactions, in continuous space or on a lattice, in two or three dimensions, in an arbitrary external potential. Some of our results generalise known relations between large-momentum behavior of the momentum distribution, short-distance behavior of the pair correlation function and of the one-body density matrix, derivative of the energy with respect to the scattering length or to time, and the norm of the regular part of the wavefunction; in the case of finite-range interactions, the interaction energy is also related to dE/da. The expression relating the energy to a functional of the momentum distribution is also generalised, and is found to break down for Efimov states with zero-range interactions, due to a subleading oscillating tail in the momentum distribution. We also obtain new expressions for the derivative of the energy of a universal state with respect to the effective range, the derivative of the energy of an efimovian state with respect to the three-body parameter, and the second order derivative of the energy with respect to the inverse (or the logarithm in the two-dimensional case) of the scattering length. The latter is negative at fixed entropy. We use exact relations to compute corrections to exactly solvable three-body problems and find agreement with available numerics. For the unitary gas, we compare exact relations to existing fixed-node Monte-Carlo data, and we test, with existing Quantum Monte Carlo results on different finite range models, our prediction that the leading deviation of the critical temperature from its zero range value is linear in the interaction effective range r_e with a model independent numerical coefficient.