Reversible Co(II)–Co(III) Transformation in a Family of Metal–Dipyrazolate Frameworks
Xiang‐Jing Kong, Tao He, Andrey A. Bezrukov, Shaza Darwish, Guang-Rui Si, Yong‐Zheng Zhang, Wei Wu, Yingjie Wang, Xia Li, Naveen Kumar, Jian‐Rong Li, Michael J. Zaworotko
Abstract
High Resolution Image Download MS PowerPoint Slide Transformation between oxidation states is widespread in transition metal coordination chemistry and biochemistry, typically occurring in solution. However, air-induced oxidation in porous crystalline solids with retention of crystallinity is rare due to the dearth of materials with high structural stability that are inherently redox active. Herein, we report a new family of such materials, four isostructural cobalt–pyrazolate frameworks of face-centered cubic, fcu, topology, fcu-L-Co, that are sustained by Co 8 molecular building blocks (MBBs) and dipyrazolate ligands, L . fcu-L-Co were observed to spontaneously transform from Co(II) 8 to Co(III) 8 MBBs in air with retention of crystallinity, marking the first such instance in metal–organic frameworks (MOFs). This transformation can also be achieved through water vapor sorption cycling, heating, or chemical oxidation. The reverse reactions were conducted by exposure of fcu-L-Co(III) to aqueous hydrazine. fcu-L-Co(II) exhibited high gravimetric water vapor uptakes of 0.55–0.68 g g –1 at 30% relative humidity (RH), while in fcu-L-Co(III) the inflection point shifted to lower RH and framework stability improved. Insight into the transformation between fcu-L-Co(II) and fcu-L-Co(III) was gained from single crystal X-ray diffraction and in situ spectroscopy. Overall, the crystal engineering approach we adopted has afforded a new family of MOFs that exhibit cobalt redox chemistry in a confined space coupled with high porosity.