Multi-particle structure in the Zn-chiral Potts models

Abstract

We calculate the lowest translationally invariant levels of the Z3- and Z4-symmetrical chiral Potts quantum chains, using numerical diagonalization of the hamiltonian for N <= 12 and N <= 10 sites, respectively, and extrapolating N to infinity. In the high-temperature massive phase we find that the pattern of the low-lying zero momentum levels can be explained assuming the existence of n-1 particles carrying Zn-charges Q = 1, ... , n-1 (mass mQ), and their scattering states. In the superintegrable case the masses of the n-1 particles become proportional to their respective charges: mQ = Q m1. Exponential convergence in N is observed for the single particle gaps, while power convergence is seen for the scattering levels. We also verify that qualitatively the same pattern appears for the self-dual and integrable cases. For general Zn we show that the energy-momentum relations of the particles show a parity non-conservation asymmetry which for very high temperatures is exclusive due to the presence of a macroscopic momentum Pm=(1-2Q/n)/φ, where φ is the chiral angle and Q is the Zn-charge of the respective particle.

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