化学
八面体
结晶学
四面体
过渡金属
价(化学)
亚稳态
双层
格子(音乐)
金属
晶体结构
化学物理
有机化学
催化作用
物理
生物化学
膜
声学
作者
Ryoya Higuchi,K. Ishida,Cédric Tassel,Baptiste Vignolle,Daichi Kato,Kantaro Murayama,Hsin‐Hui Huang,Akihide Kuwabara,Shunsuke Kobayashi,Yusuke Nambu,Hiroyasu Matsudaira,Shunsaku Kitagawa,K. Ishida,Congling Yin,Hiroshi Takatsu,Hiroshi Kageyama
摘要
Topochemical reactions in transition metal oxides, typically involving oxygen removal or anion exchange, provide a versatile platform for creating metastable phases with diverse functionalities. While these reactions often modify the valence and coordination environment of transition metals, the underlying metal frameworks are usually preserved, maintaining a 1:1 structural correspondence. A representative example is SrFeO3 → SrFeO2, in which each octahedral layer transforms into a single square-planar layer. In this study, we report an unprecedented topochemical transformation in Mo2Ta2O11, composed of alternating MoO4 tetrahedral bilayers and TaO6 octahedral bilayers. Ammonolysis at 500 °C in the presence of Mo(CO)6 collapses the MoO4 tetrahedral bilayer into a single MoO6 octahedral layer, thereby breaking the conventional 1:1 structural correspondence. This collapse leads to an 18% contraction along the c axis, substantially exceeding the 10% contraction seen in SrFeO2. The resulting compound, Mo3Ta2O10N (space group R-3m), has an Mo-based kagomé lattice with finite d-electrons (Mo4.33+), in sharp contrast to the d0 configuration of the precursor (Mo6+2Ta5+2O11). Magnetic susceptibility and NMR measurements suggest that Mo3Ta2O10N is an itinerant kagomé system. This study demonstrates that topochemical reactions can induce dynamic and extensive structural reorganizations, pushing the boundaries of what was previously considered accessible by such low-temperature routes.
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