posted on 2018-01-17, 00:00authored byKaroline Stolze, Jing Tao, Fabian O. von Rohr, Tai Kong, Robert J. Cava
We
have synthesized previously unreported high-entropy alloys (HEAs)
in the pentanary (ScZrNb)1–x[RhPd]x and hexanary (ScZrNbTa)1–x[RhPd]x systems. The
materials have CsCl-type structures and mixed site occupancies. Both
HEAs are type-II superconductors with strongly varying critical temperatures
(Tc’s) depending on the valence
electron count (VEC); the Tc’s
increase monotonically with decreasing VEC within each series, and
do not follow the trends seen for either crystalline or amorphous
transition metal superconductors. The (ScZrNb)0.65[RhPd]0.35 HEA with the highest Tc, ∼9.3
K, also exhibits the largest μ0Hc2(0) = 10.7 T. The pentanary and hexanary HEAs have higher
superconducting transition temperatures than their simple binary intermetallic
relatives with the CsCl-type structure and a surprisingly ductile
mechanical behavior. The presence of niobium, even at the 20% level,
has a positive impact on the Tc. Nevertheless,
niobium-free (ScZr)0.50[RhPd]0.50, as mother-compound
of both superconducting HEAs found here, is itself superconducting,
proving that superconductivity is an intrinsic feature of the bulk
material.