Two-Dimensional Nature of Four-Layer Superconductors by Inequivalent Hole Distribution
Abstract
The magnetization of the four-layer superconductor CuBa2Ca3Cu4O12-δ with Tc117 K is presented. The high-field magnetization around Tc(H) follows the exact two-dimensional scaling function given by Tesanovi\'c and Andreev. This feature is contrary to the inference that the interlayer coupling becomes strong if the number of CuO2 planes in a unit cell increases. Also, the fluctuation-induced susceptibility in the low-field region was analyzed by using the modified Lawrence-Doniach model. The effective number of independently fluctuating CuO2 layers per unit cell, g eff, turned out to be 2 rather than 4, which indicated that two among the four CuO2 layers were in states far from their optimal doping levels. This result could explain why CuBa2Ca3Cu4O12-δ shows two-dimensional behavior.
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