Semiclassical analysis of distinct square partitions

Abstract

We study the number P(n) of partitions of an integer n into sums of distinct squares and derive an integral representation of the function P(n). Using semi-classical and quantum statistical methods, we determine its asymptotic average part Pas(n), deriving higher-order contributions to the known leading-order expression [M. Tran et al., Ann.\ Phys.\ (N.Y.) 311, 204 (2004)], which yield a faster convergence to the average values of the exact P(n). From the Fourier spectrum of P(n) we obtain hints that integer-valued frequencies belonging to the smallest Pythagorean triples (m,p,q) of integers with m2+p2=q2 play an important role in the oscillations of P(n). Finally we analyze the oscillating part δ P(n)=P(n)-Pas(n) in the spirit of semi-classical periodic orbit theory [M. Brack and R. K. Bhaduri: Semiclassical Physics (Bolder, Westview Press, 2003)]. A semi-classical trace formula is derived which accurately reproduces the exact δ P(n) for n > 500 using 10 pairs of `orbits'. For n > 4000 only two pairs of orbits with the frequencies 4 and 5 -- belonging to the lowest Pythagorean triple (3,4,5) -- are relevant and create the prominent beating pattern in the oscillations. For n > 100,000 the beat fades away and the oscillations are given by just one pair of orbits with frequency 4.