Superconductivity and magnetic and transport properties of single-crystalline CaK(Fe1-xCrx)4As4

Abstract

Members of the CaK(Fe1-xCrx)4As4 series have been synthesized by high-temperature solution growth in single crystalline form and characterized by X-ray diffraction, elemental analysis, magnetic and transport measurements. The effects of Cr substitution on the superconducting and magnetic ground states of CaKFe4As4 (Tc = 35 K) have been studied. These measurements show that the superconducting transition temperature decreases monotonically and is finally suppressed below 1.8 K as x is increased from 0 to 0.038. The magnetic transition temperature increases in a roughly linear manner as Cr substitution increases. A temperature-composition (T-x) phase diagram is constructed, revealing a half-dome of superconductivity with the magnetic transition temperature, T*, appearing near 22~K for x 0.017 and rising slowly up to 60~K for x 0.077. The T-x phase diagrams for CaK(Fe1-xTx)4As4 for T = Cr and Mn are essentially the same despite the nominally different band filling; this is in marked contrast to T = Co and Ni series for which the T-x diagrams scale by a factor of two, consistent with the different changes in band filling Co and Ni would produce when replacing Fe. Superconductivity of CaK(Fe1-xCrx)4As4 is also studied as a function of magnetic field. A clear change in Hc2(T)/Tc, where Hc2(T) is dHc2(T)/dT, at x 0.012 is observed and probably is related to change of the Fermi surface due to magnetic order. Coherence length and the London penetration depths are also calculated based on Hc1 and Hc2 data. Coherence lengths as the function of x also shows changes near x = 0.012, again consistent with Fermi surfaces changes associated with the magnetic ordering seen for higher x-values.