Thermodynamic and single-ion properties of Tb3+ within the collective paramagnetic-spin liquid state of the frustrated pyrochlore antiferromagnet Tb2Ti2O7

In a recent paper [J. S. Gardner et al., Phys. Rev; Lett. 82, 1012 (1999)] it was found that the Tb3+ magnetic moments in the Tb2Ti2O7 antiferromagnetic pyrochlore lattice of corner-sharing tetrahedra remain in a collective paramagnetic state down to 70 mK. Ln this paper we present results from de magnetic susceptibility, specific-heat data, inelastic neutron-scattering measurements, and crystal-field calculations that strongly suggest that (i) the Tb3+ ions in Tb2Ti2O7 possess a moment of approximatively 5 mu(B), and (ii) the ground state g-tensor is extremely anisotropic below a temperature of O(10(0)) K, with Ising-like Tb3+ magnetic moments confined to point along a local cubic [111] diagonal (e.g., towards the middle of the tetrahedron). Such a very large easy-axis Ising-like anisotropy along a [111] direction dramatically reduces the frustration otherwise present in a Heisenberg pyrochlore antiferromagnet. The results presented herein underpin the conceptual difficulty in understanding the microscopic mechanism(s) responsible for Tb2Ti2O7 failing to develop long-range order at a temperature of the order of the paramagnetic Curie-Weiss temperature theta(CW)approximate to -10(1) K. We suggest that dipolar interactions and extra perturbative exchange coupling(s) beyond nearest neighbors may be responsible for the lack of ordering of Tb2Ti2O7.