Singular ferromagnetic susceptibility of the transverse-field Ising antiferromagnet on the triangular lattice

Abstract

A transverse magnetic field is known to induce antiferromagnetic three-sublattice order of the Ising spins σz in the triangular lattice Ising antiferromagnet at low enough temperature. This low-temperature order is known to melt on heating in a two-step manner, with a power-law ordered intermediate temperature phase characterized by power-law correlations at the three-sublattice wavevector Q: σz(R) σz(0) ( Q· R) /|R|η(T) with the temperature-dependent power-law exponent η(T) ∈ (1/9,1/4). Here, we use a newly developed quantum cluster algorithm to study the ferromagnetic easy-axis susceptibility u(L) of an L × L sample in this power-law ordered phase. Our numerical results are consistent with a recent prediction of a singular L dependence u(L) L2- 9 η when η(T) is in the range (1/9,2/9). This finite-size result implies, via standard scaling arguments, that the ferromagnetic susceptibility u(B) to a uniform field B along the easy axis is singular at intermediate temperatures in the small B limit, u(B) |B|-4 - 18 η4-9η for η(T) ∈ (1/9, 2/9), although there is no ferromagnetic long-range order in the low temperature state.