We revisit the important issue of charge fluctuations in the two-dimensional t−J model by using an improved variational method based on a wave function that contains both the antiferromagnetic and the d-wave superconducting order parameters. In particular, we generalize the wave function introduced some time ago by J.P. Bouchaud, A. Georges, and C. Lhuillier [J. de Physique {\bf 49}, 553 (1988)] by considering also a {\it long-range} spin-spin Jastrow factor, in order to correctly reproduce the small-q behavior of the spin fluctuations. We mainly focus our attention on the physically relevant region J/t∼0.4 and find that, contrary to previous variational ansatz, this state is stable against phase separation for small hole doping. Moreover, by performing projection Monte Carlo methods based on the so-called fixed-node approach, we obtain a clear evidence that the t−J model does not phase separate for J/t≲0.7 and that the compressibility remains finite close to the antiferromagnetic insulating state.
Finite compressibility in the low-doping region of the two-dimensional t-J model / Lugas, M.; Spanu, L.; Becca, F.; Sorella, S.. - In: PHYSICAL REVIEW. B, CONDENSED MATTER AND MATERIALS PHYSICS. - ISSN 1098-0121. - 74:16(2006), pp. 165122.1-165122.10. [10.1103/PhysRevB.74.165122]
Finite compressibility in the low-doping region of the two-dimensional t-J model
Becca, F.;Sorella, S.
2006-01-01
Abstract
We revisit the important issue of charge fluctuations in the two-dimensional t−J model by using an improved variational method based on a wave function that contains both the antiferromagnetic and the d-wave superconducting order parameters. In particular, we generalize the wave function introduced some time ago by J.P. Bouchaud, A. Georges, and C. Lhuillier [J. de Physique {\bf 49}, 553 (1988)] by considering also a {\it long-range} spin-spin Jastrow factor, in order to correctly reproduce the small-q behavior of the spin fluctuations. We mainly focus our attention on the physically relevant region J/t∼0.4 and find that, contrary to previous variational ansatz, this state is stable against phase separation for small hole doping. Moreover, by performing projection Monte Carlo methods based on the so-called fixed-node approach, we obtain a clear evidence that the t−J model does not phase separate for J/t≲0.7 and that the compressibility remains finite close to the antiferromagnetic insulating state.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
