Dr. Götz Schuck

Magnetic ions (Mn) were substituted in MgB₂ single crystals resulting in a strong pair-breaking effect. The superconducting transition temperature, T_c, in Mg_1–xMn_xB₂ has been found to be rapidly suppressed at an initial rate of 10 K/%Mn, leading to a complete suppression of superconductivity at about 2% Mn substitution. This reflects the strong coupling between the conduction electrons and the 3d local moments, predominantly of magnetic character, since the nonmagnetic ion substitutions, e.g., with Al or C, suppress T_c much less effectively (e.g., 0.5 K/%Al). The magnitude of the magnetic moment (1.7 µ_B per Mn), derived from normal state susceptibility measurements, uniquely identifies the Mn ions to be divalent, and to be in the low-spin state (S=1/2). This has been found also in x-ray absorption spectroscopy measurements. Isovalent Mn²⁺ substitution for Mg²⁺ mainly affects superconductivity through spin-flip scattering reducing T_c rapidly and lowering the upper critical field anisotropy H^ab_c2/H^c_c2 at T=0 from 6 to 3.3 (x=0.88% Mn), while leaving the initial slope dH_c2/dT near T_c unchanged for both field orientations.

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