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Bohm, T., Kretzschmar, F., Baum, A., Rehm, M., Jost, D., Ahangharnejhad, R.H., Thomale, T., Platt, C., Maier, T.A., Hanke, W., Moritz, B., Devereaux, T.P., Scalapino, D.J., Maiti, S., Hirschfeld, P.J., Adelmann, P., Wolf, T., Hai-Hu Wen, H.-H. and Rudi Hackl, R. (2018) Microscopic Origin of Cooper Pairing in the Iron-Based Superconductor Ba1?xKxFe2As2. Nature Physics Journal: Quantum Materials, 3, Article No. 48.
has been cited by the following article:
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TITLE:
Electronic Specific Heat of Iron Pnictides Based on Electron-Cooper Pair Interaction
AUTHORS:
Abel Mukubwa
KEYWORDS:
Superconductivity, Iron Pnictides, Specific Heat Capacity
JOURNAL NAME:
Open Access Library Journal,
Vol.5 No.12,
December
28,
2018
ABSTRACT: The discovery of iron pnictides in 2006 added on the number of materials that have the potential to transmit electricity with close zero d.c resistance. High-temperature iron-based superconductors have been obtained through modification, mostly by doping, of the initially low-temperature iron-based superconductors. Unlike in LTSC, the energy gap in HTSC requires a theory, beyond spin fluctuations, to explain its anisotropy. This study seeks to establish a common ground between iron pnictides and cuprates towards explaining high temperature superconductivity. There is a general consensus on the existence of Cooper pairs in these systems. In addition to this, experimental results have revealed the existence of electron-boson coupling in iron pnictides. These results make it viable to study the interaction between an electron and a Cooper pair in iron based superconductors (IBSC). In this study, Bogoliubov-Valatini transformation has been used in determining the electronic specific heat based on the interaction between an electron and a Cooper pair in high-temperature IBSC, namely, Ca0.33Na0.6Fe2As2 and SmFeAsO0.8F0.2. We record the theoretical electronic specific heat of CeFeAsO0.84F0.16 and SmFeAsO0.8F0.2 as 164.3 mJ mol-1 K-2 and 101.6 mJ mol-1 K-2 respectively.