Finite temperature physics of 1D topological Kondo insulator: Stable Haldane phase, Emergent energy scale and Beyond

Abstract

We have studied the one-dimensional p-wave periodic Anderson model at finite temperature with the help of the numerically exact determinant quantum Monte Carlo simulation. It is found that the topological Haldane phase established for ground-state is still stable against small thermal fluctuation and its characteristic edge magnetization develops at low temperature. Moreover, the saturated low-T spin structure factor and the 1T-law of susceptibility are useful to detect the free edge spin moment, which may be relevant for experimental explorations. We have also comparatively studied the conventional s-wave periodic Anderson model, which helps us identify an emergent energy scale Tcr. Tcr signals a crossover into interesting low-T regime and seems to be the expected Ruderman-Kittel-Kasuya-Yosida (RKKY) coupling. Finally, the collective Kondo screening effect has been examined and it is heavily reduced at boundary, which may give a fruitful playground for novel physics beyond the well-established Haldane state and topological band insulators.