A frustrated honeycomb-bilayer Heisenberg antiferromagnet: The spin-12 J1--J2--J1 model

Abstract

We use the coupled cluster method to study the zero-temperature quantum phase diagram of the spin-12 J1--J2--J1 model on the honeycomb bilayer lattice. In each layer we include both nearest-neighbor and frustrating next-nearest-neighbor antiferromagnetic exchange couplings, of strength J1>0 and J2 J1 > 0, respectively. The two layers are coupled by an interlayer nearest-neighbor exchange, with coupling constant J1 δ J1>0. We calculate directly in the infinite-lattice limit both the ground-state energy per spin and the N\'eel magnetic order parameter, as well as the triplet spin gap. By implementing the method to very high orders of approximation we obtain an accurate estimate for the full boundary of the N\'eel phase in the δ plane. For each value δ < δc>(0) ≈ 1.70(5) we find an upper critical value c(δ), such that N\'eel order is present for < c(δ). Conversely, for each value < c(0) ≈ 0.19(1) we find an upper critical value δc>(), such that N\'eel order persists for 0 < δ < δc>(). Most interestingly, for values of in the range c(0) < < > ≈ 0.215(2) we find a reentrant behavior such that N\'eel order exists only in the range δc<() < δ < δc>(), with δc<()>0. These latter upper and lower critical values coalesce when = >, such that δc<(>) = δc>(>) ≈ 0.25(5).