Ordering phenomena in a heterostructure of frustrated and unfrustrated triangular-lattice Ising layers

Abstract

We study critical and magnetic properties of a bilayer Ising system consisting of two triangular planes A and B, with the antiferromagnetic (AF) coupling J A and the ferromagnetic (FM) one J B for the respective layers, which are coupled by the interlayer interaction J AB by using Monte Carlo simulations. When J A and J B are of the same order, the unfrustrated FM plane orders first at a high temperature Tc1 J B. The spontaneous FM order then exerts influence on the other frustrated AF plane as an effective magnetic field, which subsequently induces a ferrimagnetic order in this plane at low temperatures below Tc2. When short-range order is developed in the AF plane while the influence of the FM plane is still small, there appears a preemptive Berezinskii-Kosterlitz-Thouless-like pseudocritical crossover regime just above the ferrimagnetic phase transition point, where the short-distance behavior up to a rather large length scale exponentially diverging in / T is controlled by a line of Gaussian fixed points at T = 0. In the crossover region, a continuous variation in the effective critical exponent 4/9 η eff 1/2 is observed. The phase diagram by changing the ratio J A/J B is also investigated.