Origin for the enhanced copper spin echo decay rate in the pseudogap regime of the multilayer high-Tc cuprates
Abstract
We report measurements of the anisotropy of the spin echo decay for the inner layer Cu site of the triple layer cuprate, Hg0.8Re0.2Ba2Ca2Cu3O8 (Tc=126 K) in the pseudogap T regime below Tpg ~ 170 K and the corresponding analysis for their interpretation. As the field alignment is varied, the shape of the decay curve changes from Gaussian (H0 c) to single exponential (H0 c). The latter characterizes the decay caused by the fluctuations of adjacent Cu nuclear spins caused by their interactions with electron spins. The angular dependence of the second moment (T2M-2 < ω2>) deduced from the decay curves indicates that T2M-2 for H0 c, which is identical to T2G-2 (T2G is the Gaussian component), is substantially enhanced, as seen in the pseudogap regime of the bilayer systems. Comparison of T2M-2 between H0 c and H0 c indicates that this enhancement is caused by electron spin correlations between the inner and the outer CuO2 layers. These results provide the answer to the long-standing controversy regarding the opposite T dependences of (T1T)-1 and T2G-2 in the pseudogap regime of bi- and trilayer systems.
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