Isoreticular tuning of pore-space-partitioned metal-organic frameworks (MOFs) provides a powerful strategy to decouple the adsorption of acetylene (C2H2) and carbon dioxide (CO2). Conventional isoreticular methods typically rely on substitution or bioisosteric replacement, which incrementally increases framework bulkiness. Herein, we report an alternative isoreticular tuning pathway that instead reduces the framework bulkiness through the incorporation of acyclic diene linkers. Using an in situ ligand transformation from trans-butene-1,4-dicarboxylic acid (tbdc), we obtained the metastable s-cis-trans, trans-muconate (scMA) linker and constructed a new series of pacs frameworks, scMA-pacs. In contrast to their conformational isomer stMA-pacs and the length-matched bdc-pacs, the scMA-based frameworks exhibit a markedly reduced CO2 affinity while maintaining high C2H2 capacity. At 298 K and 1 bar, InNi-scMA-pacs achieves a C2H2/CO2 capacity ratio of 3.2, an ideal adsorbed solution theory (IAST) selectivity of 5.80 (50:50 mixture), and a breakthrough separation window of 44 min/g, outperforming its stMA and bdc analogues. These results establish acyclic diene replacement as a distinct and effective isoreticular tuning strategy to optimize pore environments and sharpen the gas separation performance in partitioned MOFs.
Zeng et al. (Wed,) studied this question.