Interpretation of high-pressure experiments on FeAs superconductors

TL;DR

This paper theoretically investigates how hydrostatic and anisotropic pressure influence the superconducting transition temperature (Tc) in FeAs superconductors, revealing doping-dependent effects consistent with experimental data and suggesting broader applicability.

Contribution

It provides a theoretical framework explaining pressure effects on Tc in FeAs superconductors, highlighting doping dependence and directional pressure influences based on a unified real-space spin-parallel pairing theory.

Findings

Negative dTc/dP in overdoped regions under high hydrostatic pressure

Positive dTc/dP in underdoped regions under high hydrostatic pressure

Tc increases with uniaxial pressure along charge stripes

Abstract

In two recent articles (cond-mat/0606177 and arXiv:0804.1615), we have suggested a unified theory of superconductivity based on the real-space spin-parallel electron pairing and superconducting mechanism and have shown that the stable hexagonal and tetragonal vortex lattices (the optimal doping phases) can be expected in the newly discovered LaO{1-x}F{x}FeAs (x0=1/7=0.1428) and SmO{1-x}F{x}FeAs (x0=1/6=0.1667), respectively. In this paper, we present a theoretical study of the effects of hydrostatic and anisotropic pressure on the superconducting transition temperature Tc of the Fe-based layered superconductors based on the above mentioned theory. Our results indicate a strong doping-dependent pressure effects on the Tc of this compound system. Under high hydrostatic pressure, we find that dTc/dP is negative when x>x0 (the so-called overdoped region) and is positive when x<x0 (the so-called underdoped region). Qualitatively, our finding is in good agreement with the existing experimental data in LaO{1-x}F{x}FeAs (x=0.11<1/7) (arXiv:0803.4266) and SmO{1-x}F{x}FeAs (x=0.13<1/6 and x=0.3>1/6) (arXiv:0804.1582). Furthermore, Tc of both overdoped and underdoped samples shows an increase with uniaxial pressure in the charge stripe direction and a decrease with pressure in the direction perpendicular to the stripes. We suggest that the mechanism responsible for the pressure effect is not specific to the iron-based family and it may also be applicable to other superconducting materials.