Deinterpenetration of IRMOF‐9.

Abstract

AbstractOne of the iconic characteristics of metal‐organic frameworks (MOFs) is the possesssion of guest‐accessible pores. Increasing pore size has a direct and often beneficial impact on a MOF's adsorption and separation properties. However, as pore size increases, the resulting void spaces are often filled by interpenetrated frameworks, where one or more networks crystallize within the pore system of another identical network, reducing the MOF's free volume and pore size. Furthermore, due to the thermodynamic favorability of interpenetration during solvothermal synthesis, techniques to synthetically differentiate interpenetrated from non‐interpenetrated MOFs are paramount. This study reports the synthesis of deinterpenetrated IRMOF‐9 via halide mediated deinterpenetrative conversion of Zn4O‐derived IRMOF‐9. IRMOF‐9, when treated with ethylammonium bromide, is quasi‐selectively etched, revealing the non‐interpenetrated analogue, IRMOF‐10 (deinterpenetrated IRMOF‐9), which can be isolated prior to complete dissolution by the bromide solution. Dye adsorption, surface area and pore size distribution analysis, and powder X‐ray diffraction are consistent with successful deinterpenetration.