Enhanced thermoelectric properties by Ir doping of PtSb2 with pyrite structure

The effects of Ir doping on the thermoelectric properties of Pt1-xIrxSb2 (x = 0, 0.01, 0.03, and 0.1) with pyrite structure were studied. Measurements of electrical resistivity rho, Seebeck coefficient S, and thermal conductivity kappa were conducted. The results showed an abrupt change from semiconducting behavior without Ir (x = 0) to metallic behavior at x = 0.01. The sample with x = 0.01 exhibited large S and low rho, resulting in a maximum power factor (S^2/rho) of 43 muW/cmK^2 at 400 K. The peculiar "pudding mold"-type electronic band dispersion could explain the enhanced thermoelectric properties in the metallic state.Comment: 3 pages, 2 figure

体外循環開始後早期にアルカレミア環境で出現する回路内の血液凝集塊形成

Purpose : This study investigated the relationship between blood clotting in the circuit soon after initiating cardiopulmonary bypass (CPB) and echinocytes that appear with alkalemia, using a recirculation circuit filled with heparinized bovine blood. Methods : Alkalemic conditions in the recirculation circuit were prepared by adding various concentrations of NaHCO3 to the priming fluid. Albumin was also added to confirm its inhibitory effect on blood clotting. Blood pH, hold-up, the pressure gradient, and red blood cell (RBC) reduction rate were monitored. Blood clots were examined microscopically. Results : Although blood pH was elevated under all experimental conditions, clotting in the circuit increased with increased concentrations of HCO3-. Albumin inhibited the clotting under the same alkalemic conditions. Microscopic findings revealed echinocytes in the blood clots. Conclusions : The shape of echinocytes was transformed by a reduction in the Donnan equilibrium ratio because of changes in pH inside and outside the RBC membrane. Blood clotting in the circuit soon after initiating CPB may be caused by echinocytes that appear under alkalemic conditions. This was inhibited by albumin, suggesting that the addition of albumin to the priming fluid may prevent such clotting in the circuit after initiating CPB.博士（医学）・甲第664号・平成29年3月15日Copyright © 2016 Japanese Journal of Extra-Corporeal Technology（日本体外循環技術医学会）This is a non-final version of an article published in final form in "http://doi.org/10.7130/jject.43.339

Superconductivity at 38 K in Iron-Based Compound with Platinum-Arsenide Layers Ca10(Pt4As8)(Fe2-xPtxAs2)5

We report superconductivity in novel iron-based compounds Ca10(PtnAs8)(Fe2-xPtxAs2)5 with n = 3 and 4. Both compounds crystallize in triclinic structures (space group P-1), in which Fe2As2 layers alternate with PtnAs8 spacer layers. Superconductivity with a transition temperature of 38 K is observed in the n = 4 compound with a Pt content of x ~ 0.36 in the Fe2As2 layers. The compound with n = 3 exhibits superconductivity at 13 K.Comment: OPEN SELECT article, 11 pages, 5 figures, 2 table

Finite-size effect on Néel temperature in antiferromagnetic nanoparticles

Muon spin relaxation/rotation (µSR) and magnetic susceptibility measurements were carried out on antiferromagnetic nanoparticles of CuO. Nanoparticles with center size of around 5 nm were prepared by ball-milling from single crystals of CuO and investigated using µSR measurements. In the ~5 nm assembly, the TN was reduced drastically to ~30 K, compared with the bulk TN=229 K. A similar effect was observed in a system of 2 to 3 nm diameter nanorods, which was synthesized by a direct solution reaction method, where TN was suppressed further to 13 K. The present work reports direct evidence of a dramatic finite-size effect on the magnetic transition temperature in antiferromagnetic systems