Temperature-regulated synthesis of carbonate-pillared zinc-triazolate frameworks for precise molecular recognition.
Jiaqi Liu, Tong Li, Qiyi Bu, Xiaowei Bai, Li Wang, Jiafeng Miao, Hao Wang, Jinping Li
Abstract
Open AccessThe efficient discrimination of industrially relevant gases, particularly those with closely analogous physicochemical properties, remains a formidable challenge within the realm of adsorptive separation technologies. Achieving satisfactory separation efficiency poses stringent requirements on the precise control over the pore structures of adsorbents. Here we introduce a strategy for the precise modulation of pore structures in a carbonate-pillared Zn-triazolate framework, Zn2(datrz)2CO3 (datrz = 3,5-diamino-1,2,4-triazolate), through the straightforward adjustment of the solvothermal synthesis temperature. Utilizing this approach, we have successfully fabricated a series of Zn2(datrz)2CO3 materials with tunable pore structures while maintaining the framework composition and overall connectivity. These materials demonstrate selective recognition for challenging gas mixtures, including C3H6/C3H8, CO2/CH4, and CO2/N2. Density functional theory (DFT) calculations confirm that the precisely engineered pore environment plays a decisive role on selective gas adsorption. Further, the high reproducibility and scalability of this temperature-controlled synthesis method underscore its immense potential for industrial-scale applications in gas purification and separation processes.