Ground-State Phase Diagram of an Anisotropic S=1/2 Ladder with Different Leg Interactions

Abstract

We explore the ground-state phase diagram of the S=1/2 two-leg ladder with different leg interactions. The xy and z components of the leg interactions between nearest-neighbor spins in the a (b) leg are respectively denoted by J l,a and l J l,a (J l,b and l J l,b). On the other hand, the xy and z components of the uniform rung interactions are respectively denoted by r J r and J r. In the above, l and r are the XXZ-type anisotropy parameters for the leg and rung interactions, respectively. This system has a frustration when J l,a J l,b<0 irrespective of the sign of J r. The phase diagram on the l (| l| ≤ 1.0) versus J l,b (-2.0≤ J l,b≤ 3.0) plane in the case where J l,a=0.2, J r=-1.0, and r = 0.5 is determined numerically. We employ the physical consideration, and the level spectroscopy and phenomenological renormalization-group analyses of the numerical date obtained by the exact diagonalization method. The resultant phase diagram contains the ferromagnetic, Haldane, N\'eel, nematic Tomonaga-Luttinger liquid (TLL), partial ferrimagnetic, and XY1 phases. Interestingly enough, the nematic TLL phase appears in the strong-rung unfrustrated region as well as in the strong-rung frustrated one. We perform the first-order perturbational calculations from the strong rung coupling limit to elucidate the characteristic features of the phase diagram. Furthermore, we make the density-matrix renormalization-group calculations for some physical quantities such as the energy gaps, the local magnetization, and the spin correlation functions to supplement the reliability of the phase diagram.