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Ga
O
(x =0, 0.018)中島 多朗*; 満田 節生*; 高橋 慶一郎*; 吉冨 啓祐*; 増田 一也*; 金子 周史*; 本間 勇紀*; 小林 悟*; 北澤 英明*; 小坂 昌史*; et al.
Journal of the Physical Society of Japan, 81(9), p.094710_1 - 094710_8, 2012/09
We have investigated effects of applied uniaxial pressure (
) on magnetic phase transitions in a triangular lattice antiferromagnet CuFeO (CFO) and a slightly Ga-substituted compound CuFeGaO (CFGO) with 
= 0.018. We have performed neutron diffraction, spherical neutron polarimetry, magnetic susceptibility and pyroelectric measurements under up to 100 MPa applied on the [1
0] surfaces of the single crystal samples.
GaO ( = 0, 0.018)中島 多朗*; 満田 節生*; 高橋 慶一郎*; 吉冨 啓祐*; 増田 一也*; 金子 周史*; 本間 勇紀*; 小林 悟*; 北澤 英明*; 小坂 昌史*; et al.
Journal of the Physical Society of Japan, 81(9), p.094710_1 - 094710_8, 2012/09
被引用回数:13 パーセンタイル:63.15(Physics, Multidisciplinary)We have investigated effects of applied uniaxial pressure () on magnetic phase transitions in a triangular lattice antiferromagnet CuFeO (CFO) and a slightly Ga-substituted compound CuFeGaO (CFGO) with = 0.018 by spherical neutron polarimetry. In both of CFO and CFGO ( = 0.018), the application of significantly increases the transition temperature from the paramagnetic phase to a collinear incommensurate antiferromagnetic phase. This suggests that the application of breaks equilateral symmetry of the triangular lattice and partially relieves geometrical spin frustration, which generally suppresses long-range magnetic orderings. Thus we demonstrated that uniaxial pressure can be an effective tool to control magnetic phase transitions in frustrated magnets.
加倉井 和久; 脇本 秀一; 松田 雅昌*; 石渡 晋太郎*; 奥山 大輔*; 田口 康二郎*; 十倉 好紀*; 西 正和*; 中島 多朗*; 満田 節生*; et al.
no journal, ,
In studying modern functional materials, one is often confronted with complex spin configurations, for example, non-collinear, incommensurate magnetic structure such as helimagnetic structure as a result of frustrated magnetic interactions. Since the giant functional responses in these materials are direct consequences of these complicated magnetic structures, the detailed knowledge of the structure is mandatory to understand the essence of the magnetic functional materials. In this presentation some recent results on complex magnetic materials such as frustrated and multiferroic systems are reported, where the polarized neutron investigations provided important insight into the complex behavior of these functional materials.
