Ground states and excitations of a one-dimensional kagome-like antiferromagnet

We study a Heisenberg antiferromagnet (AF) on a one-dimensional strip composed of two rows of corner sharing triangular plaquettes. The geometry of this ladder-like lattice naturally allows for two different exchange couplings, one between pairs of spins on the outer legs (J) and a different one between the spies on the axis and their nearest neighbors on the legs (J'). For J/J' less than or similar to 0.5 the model is a ferrimagnet. Our main interest is in the region J/J' greater than or similar to 0.5, when the classical ground state of this system shows the same macroscopic degeneracy as the classical ground state of the antiferromagnet on the kagome lattice. To explore to which extent this similarity between the classical ground states of these two models carries over to their quantum states we have applied exact diagonalization techniques and density-matrix renormalization group (DMRG) methods to our model. Exact diagonalization is restricted to system sizes of up to N = 30 sites. Fur J/J' = I, the results obtained by this technique, low-energy spectra, correlation functions and the specific heat, agree qualitatively with the results obtained for finite samples of the kagome AF. As in the case of the kagome AF, these finite size results suggest that our model is a spin liquid with a gap between the ground state and the lowest spin excitation. However, extrapolations from DMRG data far strips of up to N = 120 sites point towards a vanishing spin gap in a wide range of couplings, 0.5 less than or similar to J/J' less than or similar to 1.25, so that contrary to the above conjecture, our one-dimensional model may in fact be critical in this parameter range. Moreover, our DMRG data indicate that the model undergoes a transition to a gapped state as the ratio J/J' increases through the value J/J' = 1.25. In the vicinity of the transition point, a high density of low-lying singlets develops in the spin gap.