The magnetic susceptibility, crystal and magnetic structures, and electronic structure of double perovskite Sr2ScOsO6 are reported. Using both neutron and x-ray powder diffraction we find that the crystal structure is monoclinic P21/n from 3.5 to 300 K. Magnetization measurements indicate an antiferromagnetic transition at T N = 92 K, one of the highest transition temperatures of any double perovskite hosting only one magnetic ion. Type I antiferromagnetic order is determined by neutron powder diffraction, with an Os moment of only 1.6(1) µ B , close to half the spin-only value for a crystal field split 5d electron state with t2g 3 ground state. Density functional calculations show that this reduction is largely the result of strong Os-O hybridization, with spin-orbit coupling responsible for only a ∼ 0.1 µ B reduction in the moment. PACS numbers: 75.25.-j, 71.15.Mb, 71.70.Ej It is important to understand the nature of the d 3 electronic state, as it appears to produce the highest magnetic transition temperatures found in perovskite systems [1]. Perovskites NaOsO 3 , 5d 3 , and SrTcO 3 , 4d 3 , have T N = 411 K and T N ≈ 1000 K, respectively [2-5]. In the double perovskite Sr 2 CrOsO 6 two d 3 ions are present, Cr 3+ 3d 3 and Os 5+ 5d 3 , and a ferrimagnetic transition with T C = 725 K is found, the highest known transition temperature in any double perovskite [6]. However, the presence of two magnetic ions in Sr 2 CrOsO 6 makes the interactions controlling this high-T C insulator more difficult to unravel [7]. It is clear that the influence of the Os 5d 3 electrons must be understood in order to ultimately understand the high-T C found in Sr 2 CrOsO 6. The d 3 electronic configuration in a perovskite-type structure is, at first sight, an unlikely host of complex magnetic behavior. The octahedral environment splits the d orbitals into t 2g and e g levels, stabilizing a half occupied t 2g 3 configuration. This is normally assumed to be fully orbitally quenched, resulting in a relatively classical S = 3/2 moment behavior [8]. However, many investigations in 4d 3 and 5d 3 compounds have found that the ordered magnetic moment measured by neutron diffrac-tion is significantly reduced from the spin only value of µ = 3 µ B [3, 9-14]. Explanations of this reduced moment have centered on covalency and frustration. It has recently been suggested, however, that the effect of spin-orbit coupling (SOC) cannot be ignored in 4d 3 and 5d 3 systems [15]. In Ref. [15] they find that the electronic state may lie between L-S and J-J coupling regimes, and therefore the t 2g 3 assumption is invalid. Recent experimental investigations have therefore discussed the role of SOC in 4d 3 and 5d 3 double perovskites [9, 16-19]. Here we investigate the magnetic insulator Sr 2 ScOsO 6 , which has one of the highest known magnetic transition temperatures in double perovskites hosting only one magnetic ion [20, 21]. It is the 3d 0 −5d 3 analogue of 3d 3 −5d 3 Sr 2 CrOsO 6 , and thus serves as a model system to unravel the behavior of d 3 Os 5+....
