Bryan J Daniel, Santangelo Steven A, Keveren Sean C, Gamelin Daniel R
Department of Chemistry, University of Washington, Seattle, WA 98195-1700, USA.
J Am Chem Soc. 2005 Nov 9;127(44):15568-74. doi: 10.1021/ja0543447.
Colloidal Co(2+)- and Cr(3+)-doped TiO(2) nanorods and nanocrystals were synthesized and studied by X-ray powder diffraction, electronic absorption spectroscopy, magnetic circular dichroism spectroscopy, magnetic susceptibility, and transmission electron microscopy. The nanorods were paramagnetic as colloids but showed room-temperature ferromagnetism when spin-coated aerobically into films. Crystalline domain size, thermal annealing, and dopant or defect migration are not the dominating factors converting the doped TiO(2) nanocrystals from the paramagnetic state to the ferromagnetic state. The most important factor for activating ferromagnetism is found to be the creation of grain boundary defects, proposed to be oxygen vacancies at nanocrystal fusion interfaces. These defects are passivated and the ferromagnetism destroyed by further aerobic annealing. These results not only help elucidate the origins of the TM(n+):TiO(2) DMS ferromagnetism but also represent an advance toward the controlled manipulation of high-T(C) DMS ferromagnetism using external chemical perturbations.
合成了胶体状的 Co(2+) 和 Cr(3+) 掺杂的 TiO(2) 纳米棒及纳米晶体,并通过 X 射线粉末衍射、电子吸收光谱、磁圆二色光谱、磁化率和透射电子显微镜对其进行了研究。纳米棒作为胶体时呈顺磁性,但在有氧条件下旋涂成膜时表现出室温铁磁性。晶畴尺寸、热退火以及掺杂剂或缺陷迁移并非将掺杂的 TiO(2) 纳米晶体从顺磁态转变为铁磁态的主导因素。发现激活铁磁性的最重要因素是晶界缺陷的产生,推测这些缺陷是纳米晶体融合界面处的氧空位。通过进一步的有氧退火,这些缺陷被钝化,铁磁性被破坏。这些结果不仅有助于阐明 TM(n+):TiO(2) 稀磁半导体铁磁性的起源,而且代表了朝着利用外部化学扰动对高居里温度稀磁半导体铁磁性进行可控操纵迈出的一步。