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山内 宏樹; Sari, D. P.*; 安井 幸夫*; 坂倉 輝俊*; 木村 宏之*; 中尾 朗子*; 大原 高志; 本田 孝志*; 樹神 克明; 井川 直樹; et al.
Physical Review Research (Internet), 6(1), p.013144_1 - 013144_9, 2024/02
-Mn-type family alloys Mn have three-dimensional antiferromagnetic (AFM) corner-shared triangular network. The antiferromagnet MnRhSi shows magnetic short-range order (SRO) over a wide temperature range of approximately 500 K above the Nel temperature = 190 K. MnCoSi has the smallest lattice parameter and the lowest in the family compounds. The quantum critical point (QCP) from AFM to the quantum paramagnetic state is expected near a cubic lattice parameter of 6.15 of MnCoSi is only 140 K, quantum critical behavior is observed in MnCoSi as the enhancement of the electronic specific heat coefficient . We study how the magnetic SRO appears in MnCoSi by using neutron scattering, SR, and physical property measurements. The experimental results show that the neutron scattering intensity of the magnetic SRO does not change much regardless of the suppressed magnetic moment in the long-range magnetic ordered state compared to those of MnRhSi. The initial asymmetry drop ratio of SR above becomes small, and the magnetic SRO temperature is suppressed to 240 K. The results suggest that the MnCoSi is close to the QCP in the Mn system.
社本 真一; 山内 宏樹; 飯田 一樹*; 池内 和彦*; Hall, A. E.*; Chen, Y.-S.*; Lee, M. K.*; Balakrishnan, G.*; Chang, L.-J.*
Communications Physics (Internet), 6, p.248_1 - 248_6, 2023/09
被引用回数:1 パーセンタイル:57.37(Physics, Multidisciplinary)MnRhSi単結晶の中性子散乱測定により、局所スピン相関秩序がらせん構造を持つことがわかった。磁気クラスター形成の起源の可能性を、リフシッツ不変量とグリフィス相の観点から議論し、CoZnMnの室温スキルミオン相とMnの非フェルミ液体挙動と比較した。
Kaufmann, S.*; Simpson, D. A.*; Hall, L. T.*; Perunicic, V.*; Senn, P.*; Steinert, S.*; McGuinness, L. P.*; Johnson, B. C.*; 大島 武; Caruso, F.*; et al.
Proceedings of the National Academy of Sciences of the United States of America, 110(27), p.10894 - 10898, 2013/07
被引用回数:107 パーセンタイル:93.29(Multidisciplinary Sciences)The detection of gadolinium (Gd) spin labels in an artificial cell membrane under ambient conditions was demonstrated using a single-spin nanodiamond sensor which is negatively charged nitrogen vacancy centers in nanodiamond. Changes in the spin relaxation time (T1) of the sensor located in the lipid bilayer were optically detected using a confocal microscope system. As a result, T1 decreased with increasing proximal Gd labels. The detection of such small numbers of spins in a model biological setting opens a new pathway for in-situ nanoscale detection of dynamical processes in biology.