Litcius/Paper detail

Complexity in Order: High-Porosity Multicomponent Metal–Organic Frameworks for Clean Energy Gas Storage

Yuanlong Zhong, Puhao Fang, Mengyang Zhai, Zi Kang Low, Zhijie Chen

2025Journal of the American Chemical Society16 citationsDOI

Abstract

The development of high-performance adsorbent materials offers a promising method for the efficient storage of clean energy gas to achieve a carbon-neutral energy cycle. Herein, we report reticular synthesis of high-porosity and structurally robust metal–organic frameworks (MOFs)─ tsn -MOF-1 with the (3,6,9)-connected tsn net─from the precise assembly of 9-connected metal μ 3 -oxo-centered trinuclear nodes, 6-connected trigonal prismatic peripherally extended triptycene carboxylate ligands, and 3-connected triangular pyridine-based ligands in a geometry- and size-matching manner. The tsn -MOF-1-Fe 3 maintains high porosity under common solvent activation conditions, exhibiting a high apparent Brunauer–Emmett–Teller surface area of 5100 m 2 g –1 and an experimental pore volume of 2.11 cm 3 g –1 . As a result, this MOF displays a good methane working capacity of 365.4 cm 3 cm –3 (0.688 g g –1 ) under a combined temperature and pressure swing condition (159 K/6 bar → 298 K/5 bar) and shows respectable potential for low-temperature methane storage. Moreover, the tsn -MOF-1-Fe 3 shows a hydrogen-deliverable capacity of 48.6 g L –1 (11.3 wt %) under a related swing condition (77 K/100 bar → 159 K/5 bar). This geometry-directed strategy allows the precise design and synthesis of high-connectivity and high-porosity multicomponent reticular structures with robust pore structures for the storage of clean energy gases.

Topics & Concepts

ChemistryTriptyceneBar (unit)AdsorptionPorosityMethaneVolume (thermodynamics)Energy storageChemical engineeringReticular connective tissueMetal-organic frameworkCarboxylateClean energyWork (physics)Pressure swing adsorptionSolventSpecific surface areaNanotechnologyAnthraciteRational designMoleculeTonHydrogen storageBarrerEnergy sourceHigh energyProcess engineeringPropanePorous mediumNatural gasMetal-Organic Frameworks: Synthesis and ApplicationsCarbon Dioxide Capture TechnologiesCarbon dioxide utilization in catalysis