Construction and selective gas adsorption properties of two heteroSBU MOFs based on unsymmetrical tetracarboxylate linkers†
Abstract
By employing the strategy of positional isomerism, we designed and synthesized two unsymmetrical biphenyl tetracarboxylate ligands, and used them to successfully construct two novel copper-based MOFs. Structural determinations show that the resulting MOFs are three-dimensional networks, each incorporating two different kinds of discrete copper-carboxylate clusters, including the typical dicopper Cu2(COO)4(H2O)2 paddlewheel, as inorganic SBUs, and they display distinctly different topologies, highlighting the significant effect of ligand desymmetrization. ZJNU-9 is a neutral coordination network composed of one typical dicopper paddlewheel and a new dicopper cluster Cu2(COO)4(DMF)2(H2O)2 connected by the organic ligands, while ZJNU-10 is based on one typical dicopper paddlewheel and a new tetracopper cluster Cu4(COO)4(OH)2Cl(H2O)4 linked by the organic ligands to a cationic framework containing three types of cages. The two novel copper-containing clusters discovered in the two compounds greatly enrich the diversity and complexity of inorganic copper-carboxylate SBUs and thus MOF structures. Furthermore, a systematical investigation of their selective adsorption properties with respect to C2H2, CO2, and CH4 through pure-component isotherm measurements and IAST predictions revealed their promising potential for C2H2 recovery and CO2 removal from CH4 under ambient conditions. This work represents a rare example of homometallic pure-carboxylate hetero-SBU MOFs exhibiting highly selective adsorption of C2H2 and CO2 over CH4.