Southon Peter D, Liu Lang, Fellows Elizabeth A, Price David J, Halder Gregory J, Chapman Karena W, Moubaraki Boujemaa, Murray Keith S, Létard Jean-François, Kepert Cameron J
School of Chemistry, The University of Sydney, NSW 2006, Australia.
J Am Chem Soc. 2009 Aug 12;131(31):10998-1009. doi: 10.1021/ja902187d.
The nanoporous metal-organic framework [Fe(pz)Ni(CN)(4)], 1 (where pz is pyrazine), exhibits hysteretic spin-crossover at ambient conditions and is robust to the adsorption and desorption of a wide range of small molecular guests, both gases (N(2), O(2), CO(2)) and vapors (methanol, ethanol, acetone, acetonitrile, and toluene). Through the comprehensive analysis of structure, host-guest properties, and spin-crossover behaviors, it is found that this pillared Hofmann system uniquely displays both guest-exchange-induced changes to spin-crossover and spin-crossover-induced changes to host-guest properties, with direct dynamic interplay between these two phenomena. Guest desorption and adsorption cause pronounced changes to the spin-crossover behavior according to a systematic trend in which larger guests stabilize the high-spin state and therefore depress the spin-crossover temperature of the host lattice. When stabilizing the alternate spin state of the host at any given temperature, these processes directly stimulate the spin-crossover process, providing a chemisensing function. Exploitation of the bistability of the host allows the modification of adsorption properties at a fixed temperature through control of the host spin state, with each state shown to display differing chemical affinities to guest sorption. Guest desorption then adsorption, and vice versa, can be used to switch between spin states in the bistable temperature region, adding a guest-dependent memory effect to this system.
纳米多孔金属有机框架[Fe(pz)Ni(CN)(4)],即1(其中pz为吡嗪),在环境条件下表现出滞后自旋交叉现象,并且对多种小分子客体(包括气体(N₂、O₂、CO₂)和蒸汽(甲醇、乙醇、丙酮、乙腈和甲苯))的吸附和解吸具有稳定性。通过对结构、主客体性质和自旋交叉行为的综合分析,发现这种柱状霍夫曼体系独特地展现了客体交换引起的自旋交叉变化以及自旋交叉引起的主客体性质变化,这两种现象之间存在直接的动态相互作用。客体的解吸和吸附会根据一种系统趋势对自旋交叉行为产生显著变化,即较大的客体稳定高自旋态,从而降低主体晶格的自旋交叉温度。在任何给定温度下稳定主体的交替自旋态时,这些过程会直接刺激自旋交叉过程,提供一种化学传感功能。利用主体的双稳态,可以通过控制主体自旋态在固定温度下改变吸附性质,每种状态对客体吸附显示出不同的化学亲和力。在双稳态温度区域,客体先解吸然后吸附,反之亦然,可用于在自旋态之间切换,为该体系增添了一种客体依赖的记忆效应。