Theory of spin nematic to spin-Peierls quantum phase transition in ultracold spin-1 atoms in optical lattices

TL;DR

This paper develops a theoretical framework for the quantum phase transition between spin nematic and spin-Peierls phases in ultracold spin-1 atoms, revealing a generally first-order transition and critical behavior in one dimension.

Contribution

It introduces a large-N SO(3N) model to analyze the transition, showing it is typically first order and identifying a critical point in 1D where multiple phases meet.

Findings

Transition is generally first order in the large-N limit.

Spin nematic phase is absent in 1D, but its correlations diverge at the critical point.

Predictions made for $^{23}$Na atoms in optical lattices.

Abstract

We present a theory of the anisotropy tuned quantum phase transition between spin nematic and spin-Peierls phases in S=1 systems with significant bi-quadratic exchange interactions. Based on quantum Monte Carlo studies on finite size systems, [K. Harada et al., J. Phys. Soc. Jpn. 76, 013703 (2007)] it has been proposed that this phase transition is second order with new deconfined fractional excitations that are absent in either of the two phases [T. Grover and T. Senthil, Phys. Rev. Lett. 98, 247202 (2007)]. The possibility of a weak first order transition, however, cannot be ruled out. To elucidate the nature of the transition, we construct a large-N SO(3N) model for this phase transition and find in the $N\to\infty$ limit that the transition is generically of first order. Furthermore, we find a critical point in the 1D limit, where two transition lines, separating spin nematic, ferromagnetic, and spin-Peierls phases, meet. Our study indicates that the spin nematic phase is absent in 1D, while its correlation length diverges at the critical point. Predictions for $^{23}$Na atoms trapped in an optical lattice, where this quantum phase transition naturally arises, are discussed.