Effects of electron irradiation on resistivity and London penetration depth of Ba1-xKxFe2As2 (x ≤ 0.34) iron - pnictide superconductor

Abstract

Irradiation with 2.5 MeV electrons at doses up to 5.2 ×1019 electrons/cm2 was used to introduce point-like defects in single crystals of Ba1-xKxFe2As2 with x= 0.19 (Tc= 14 K), x= 0.26 (Tc= 32 K) and 0.34 (Tc= 39 K) to study the superconducting gap structure by probing the effect of non-magnetic scattering on electrical resistivity, (T), and London penetration depth, λ (T). For all compositions, the irradiation suppressed the superconducting transition temperature, Tc and increased resistivity. The low - temperature behavior of λ (T) is best described by the power - law function, λ (T) = A(T/Tc)n. While substantial suppression of Tc supports s pairing mechanism, in samples close to the optimal doping, x= 0.26 and 0.34, the exponent n remained high (n ≥ 3) indicating robust full superconducting gaps. For the x= 0.19 composition, exhibiting coexistence of superconductivity and long - range magnetism, the suppression of Tc was much more rapid and the exponent n decreased toward dirty limit of n = 2. In this sample, the irradiation also suppressed the temperature of structural/magnetic transition, Tsm, from 103 K to 98 K consistent with the itinerant nature of the magnetic order. Our results suggest that underdoped compositions, especially in the coexisting regime are most susceptible to non-magnetic scattering and imply that in multi-band Ba1-xKxFe2As2 superconductors, the ratio of the inter-band to intra-band pairing strength, and associated gap anisotropy, increases upon the departure from the optimal doping.