Condensates, crystals, and renormalons in the Gross-Neveu model at finite density

Abstract

We study the O(2N) symmetric Gross-Neveu model at finite density in the presence of a U(1) chemical potential h for a generic number a ≤ N-2 of fermion fields. By combining perturbative quantum field theory, semiclassical large N, and Bethe ansatz techniques, we show that at finite N two new dynamically generated scales n and c appear in the theory, governing the mass gap of neutral and charged fermions, respectively. Above a certain threshold value for h, a-fermion bound states condense and form an inhomogeneous configuration, which at infinite N is a crystal spontaneously breaking translations. At large h, this crystal has mean n and spatial oscillations of amplitude 2c. The two scales also control the nonperturbative corrections to the free energy, resolving a puzzle concerning fractional-power renormalons and predicting new ones.