Quantum Density of States and Integer Partitions: A Semiclassical Approach
Abstract
In this review we discuss semi-classical methods that are traditionally used to describe many-body systems in physics, but may also be used to describe partitions of integers in analytic number theory.
Specifically, we explore the connection between the methods of statistical mechanics and number partitions.
Though the two fields appear very different, their fundamental issues bear a close resemblance.
In the former case it is the distribution of a given amount of energy among the particles in an ensemble at a given temperature with well defined properties, while in the latter case it is the way an integer is partitioned into other integers, with or without restrictions.
We begin with a discussion of the single-particle quantum density of states, also called the level density, in which we illustrate the connection between the density of states and the classical periodic orbits through the semiclassical trace formula.
This is then extended to many particle systems.
We show that the asymptotic number partition is reproduced by the average (smooth) part of the level density at discrete integer values of the argument.
In the especially interesting case of distinct square partitions, pronounced oscillations are well reproduced by the periodic orbit theory in terms of a few orbits characterised by Pythagorean number triples.
We speculate on the connection to Fermat's theorem as to why such regular oscillations (though vanishing asymptotically) exist only in this special case.
Finally, we discuss some new results for integer partitions of primes, both unrestricted and distinct.
이 뉴스, 어떠셨어요?
한 번의 탭으로 반응을 남겨요 · 로그인 불필요