Enhancing the singlet oxygen capture and release rate of metal−organic frameworks through interpenetration tuning

Recognized as one of the important active species involved in various reactions, singlet oxygen (1O2) shows potential applications in chemical, biological, and environmental related fields. However, the controlled capture and release of 1O2 are still facing huge challenges due to its short lifetime and high reactivity. Herein, a framework-interpenetration tuning strategy was applied on a metal-organic framework (MOF) that aiming to improve the capture and release rate of 1O2. The porosity of the MOF was remarkably enhanced with the structural evolution from seven-fold (termed NKM-181) to six-fold interpenetration (termed NKM-182), and the active anthracene sites became much more accessible. Such drastic process can be achieved as simple as exchanging the primitive MOF in selected solvent and occurred surprisingly as single-crystal to single-crystal transformation. Also, additionally owing to the unblocked regular channels, NKM-182 shown significantly improved 1O2 trapping and releasing rates compared to that of in NKM-181. This work demonstrates an unprecedented regulation of 1O2 capture and release process, along with achieving the highest 1O2 capture and release rate among reported porous materials. Furthermore, the obtained endoperoxides with 1O2 loaded (termed EPO-NKM-181 and EPO-NKM-182) can be used as a high efficiency smart material for anti-fake application