Evidences of the Generalizations of BKT Transition in Quantum Clock Model

Abstract

We calculate the ground state energy density ε(g) for the one dimensional N-state quantum clock model up to order 18, where g is the coupling and N=3,4,5,...,10,20. Using methods based on Pad\'e approximation, we extract the singular structure of ε''(g) or ε(g). They correspond to the specific heat and free energy of the classical 2D clock model. We find that, for N=3,4, there is a single critical point at gc=1.The heat capacity exponent of the corresponding 2D classical model is α=0.340.01 for N=3, and α=-0.01 0.01 for N=4. For N>4, There are two exponential singularities related by gc1=1/gc2, and ε(g) behaves as Ae-c|gc-g|σ+analytic\ terms near gc. The exponent σ gradually grows from 0.2 to 0.5 as N increases from 5 to 9, and it stabilizes at 0.5 when N>9. These phase transitions should be generalizations of Kosterlitz-Thouless transition, which has σ=0.5. The physical pictures of these phase transitions are still unclear.