Effect of a Normal-State Pseudogap on Optical Conductivity in Underdoped Cuprate Superconductors
Abstract
We calculate the c-axis infrared conductivity σc(ω) in underdoped cuprate superconductors for spinfluctuation exchange scattering within the CuO2-planes including a phenomenological d-wave pseudogap of amplitude Eg. For temperatures decreasing below a temperature T* Eg/2, a gap for ω < 2Eg develops in σc(ω) in the incoherent (diffuse) transmission limit. The resistivity shows 'semiconducting' behavior, i.e. it increases for low temperatures above the constant behavior for Eg=0. We find that the pseudogap structure in the in-plane optical conductivity is about twice as big as in the interplane conductivity σc(ω), in qualitative agreement with experiment. This is a consequence of the fact that the spinfluctuation exchange interaction is suppressed at low frequencies as a result of the opening of the pseudogap. While the c-axis conductivity in the underdoped regime is described best by incoherent transmission, in the overdoped regime coherent conductance gives a better description.
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