Effect of anisotropy on the ground-state magnetic ordering of the spin-half quantum J1XXZ--J2XXZ model on the square lattice

Abstract

We study the zero-temperature phase diagram of the 2D quantum J1XXZ--J2XXZ spin-1/2 anisotropic Heisenberg model on the square lattice. In particular, the effects of the anisotropy on the z-aligned N\'eel and (collinear) stripe states, as well as on the xy-planar-aligned N\'eel and collinear stripe states, are examined. All four of these quasiclassical states are chosen in turn as model states on top of which we systematically include the quantum correlations using a coupled cluster method analysis carried out to very high orders. We find strong evidence for two quantum triple points (QTP's) at ( c = -0.10 0.15, J2c/J1 = 0.505 0.015) and ( c = 2.05 0.15, J2c/J1 = 0.530 0.015), between which an intermediate magnetically-disordered phase emerges to separate the quasiclassical N\'eel and stripe collinear phases. Above the upper QTP ( 2.0) we find a direct first-order phase transition between the N\'eel and stripe phases, exactly as for the classical case. The z-aligned and xy-planar-aligned phases meet precisely at = 1, also as for the classical case. For all values of the anisotropy parameter between those of the two QTP's there exists a narrow range of values of J2/J1, αc1()<J2/J1 <αc2(), centered near the point of maximum classical frustration, J2/J1 = 1/2, for which the intermediate phase exists. This range is widest precisely at the isotropic point, = 1, where αc1(1) = 0.44 0.01 and αc2(1) = 0.59 0.01. The two QTP's are characterized by values = c at which αc1(c)=αc2(c).