Temperature-independent pseudogap and thermally activated c-axis hopping conductivity in layered cuprate superconductors

•Carrier localization (confinement) and pseudogap formation in cuprates are discussed.•A new theoretical model of c-axis charge transport in layered cuprates is proposed.•A good quantitative agreement was found between the theory and experimental data. The carrier localization (confinement) and c-ax...

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Bibliographic Details
Published in:Superlattices and microstructures 2014-04, Vol.68, p.6-15
Main Authors: Dzhumanov, S., Karimboev, E.X., Kurbanov, U.T., Ganiev, O.K., Djumanov, Sh.S.
Format: Article
Language:English
Subjects:
Activated
c-Axis charge transport
Carriers
Charge transport
Confinement
COPPER OXIDE
Cuprate superconductors
Cuprates
ELECTRICAL CONDUCTIVITY
Electron–phonon interactions
Localized (bi)polarons
MATHEMATICAL ANALYSIS
Mathematical models
MICROSTRUCTURES
Nanoscale phase separation
Nanostructure
Pseudogap formation
SUPERCONDUCTORS
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Summary:•Carrier localization (confinement) and pseudogap formation in cuprates are discussed.•A new theoretical model of c-axis charge transport in layered cuprates is proposed.•A good quantitative agreement was found between the theory and experimental data. The carrier localization (confinement) and c-axis charge transport in high-Tc layered cuprates have been investigated in the temperature-independent pseudogap state over a wide doping range from the underdoped to the overdoped regime, focusing on the nanoscale phase separation into two different domains (i.e. carrier-rich CuO2 layers and carrier-poor regions between the CuO2 layers) caused by inherent nanoscale electronic inhomogeneities and on the real-space pairing of polaronic carriers caused by strong electron–phonon interactions in carrier-poor regions. A simple microscopic model for layered cuprate superconductors is proposed to describe the carrier confinement and formation of localized bipolarons in the low-doping regions between the CuO2 layers and to simulate the c-axis hopping transport at the thermal dissociation of such bipolarons. This model is found to describe properly the c-axis charge transport, which is governed by thermally activated hopping of polarons residing in the localized state between the CuO2 layers due to the existence of the temperature-independent bipolaronic pseudogap, and the insulating behavior of the c-axis resistivity ρc(T) observed above Tc in various cuprate superconductors, from the underdoped to the overdoped regime. It is found that the insulating behavior of ρc(T) is changed to metallic behavior with disappearing of bipolaronic pseudogap.
ISSN:0749-6036
1096-3677
DOI:10.1016/j.spmi.2014.01.004