Coherent quasiparticle weight and its connection to high-Tc superconductivity from angle-resolved photoemission
Abstract
In conventional superconductors, the pairing energy gap () and superconducting phase coherence go hand-in-hand. As the temperature is lowered, both the energy gap and phase coherence appear at the transition temperature Tc. In contrast, in underdoped high-Tc superconductors (HTSCs), a pseudogap appears at a much higher temperature T*, smoothly evolving into the superconducting gap at Tc. Phase coherence on the other hand is only established at Tc, signaled by the appearance of a sharp quasiparticle (QP) peak in the excitation spectrum. Another important difference between the two types of superconductors is in the ratio of 2 / Tc=R. In BCS theory, R~3.5, is constant. In the HTSCs this ratio varies widely, continuing to increase in the underdoped region, where the gap increases while Tc decreases. Here we report that in HTSCs it is the ratio zAm/Tc which is approximately constant, where m is the maximum value of the d-wave gap, and zA is the weight of the coherent excitations in the spectral function. This is highly unusual, since in nearly all phase transitions, Tc is determined by an energy scale alone. We further show that in the low-temperature limit, z A increases monotonically with increasing doping x. The growth is linear, i.e. zA(x) x, in the underdoped to optimally doped regimes, and slows down in overdoped samples. The reduction of zA with increasing temperature resembles that of the c-axis superfluid density.
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