The authors report measurements of the planar 63 Cu nuclear spin-lattice relaxation rates 63 H / u / ( 63 W| r ) for the static field oriented along the a (c) axis in the superconducting state of YBa2Cu307. These measurements were made on a single sample as a function of temperature and magnetic field. The weak-field results are well explained by several recent calculations in terms of a BCS spin-singlet, orbital-d-wave pairing state. They also find that at low temperatures bi W\ c varies linearly with the applied magnetic field, suggesting that at high field it is dominated by fluxoid cores. PACS numbers: 74.70.Vy, 74.30.Gn, 76.60.Es, 76.60.Gv Nuclear spin-lattice relaxation time measurements in superconductors have provided information about the nature of the superconducting state [l]. They have been employed extensively in the study of Cu02-based hightemperature superconductors [2,3]. Recently we reported [4] that measurements below T v of the relaxation rates of the planar 63 Cu, ,7 0, and 89 Y nuclei in YBa 2 Cu 3 0 7 had puzzling properties, especially when viewed in the framework of the antiferromagnetic Fermi liquid (AFL) theory [5], which is so successful in describing the NMR properties of the normal state of high-temperature superconductors. In this Letter we report significant new experimental results, and compare them with recent calculations of Bulut and Scalapino [6], Lu [7], and Lu and Pines [8], which successfully account for the results. These results suggest that YBa2Cu37 is a superconductor of the BCS variety with spin-singlet pairing and nodes in the gap (as in t/-wave pairing).In the normal state the nuclear spin-lattice relaxation rates n W\ a are anisotropic [r/=63, 17, or 89 corresponding to the planar 63 Cu(2), l7 0(2,3), or 89 Y nuclei, where a=a or c specifies the orientation of the static applied field]. For the Cu(2) in the normal state, b3 W ]a / b3 W u . = 3.4-3.7 (depending on the sample) and is independent of temperature and magnetic field strength [4,9]. In our earlier paper we reported that below T c the ratio dropped substantially and was temperature dependent, a result which was hard to understand within the AFL framework [4]. We studied the ratio at 8.31 T and also, at 77 K, in a weak field (0.45 T). The latter experiment proved that the change in b3 W\J^3W\ c just below T c was not an artifact resulting from the presence of the static magnetic field. However, our data for b3 W\ c . measured at zero field [nuclear quadrupole resonance (NQR)] in one sample and at 8.31 T in another sample had slightly different temperature dependences, deviating from each other progressively as one went to lower temperatures. It was not clear whether this was a sample dependence or a field dependence.In our present work, we have measured relaxation rates in strong, intermediate, weak, and zero fields in a single sample. We find that as one lowers T through T c in weak fields, the anisotropy ratio b3 W\ a / b3 W\ c first drops (as we showed previously) [4] then rises above the normal-state v...
