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Balancing volumetric and gravimetric uptake in highly porous materials for clean energy.

Zhijie ChenPenghao LiRyther AndersonXingjie WangXuan ZhangLee RobisonLouis R RedfernShinya MoribeTimur IslamogluDiego A Gómez-GualdrónTaner YildirimJ Fraser StoddartOmar K Farha
Published in: Science (New York, N.Y.) (2020)
A huge challenge facing scientists is the development of adsorbent materials that exhibit ultrahigh porosity but maintain balance between gravimetric and volumetric surface areas for the onboard storage of hydrogen and methane gas-alternatives to conventional fossil fuels. Here we report the simulation-motivated synthesis of ultraporous metal-organic frameworks (MOFs) based on metal trinuclear clusters, namely, NU-1501-M (M = Al or Fe). Relative to other ultraporous MOFs, NU-1501-Al exhibits concurrently a high gravimetric Brunauer-Emmett-Teller (BET) area of 7310 m2 g-1 and a volumetric BET area of 2060 m2 cm-3 while satisfying the four BET consistency criteria. The high porosity and surface area of this MOF yielded impressive gravimetric and volumetric storage performances for hydrogen and methane: NU-1501-Al surpasses the gravimetric methane storage U.S. Department of Energy target (0.5 g g-1) with an uptake of 0.66 g g-1 [262 cm3 (standard temperature and pressure, STP) cm-3] at 100 bar/270 K and a 5- to 100-bar working capacity of 0.60 g g-1 [238 cm3 (STP) cm-3] at 270 K; it also shows one of the best deliverable hydrogen capacities (14.0 weight %, 46.2 g liter-1) under a combined temperature and pressure swing (77 K/100 bar → 160 K/5 bar).
Keyphrases
  • metal organic framework
  • anaerobic digestion
  • carbon dioxide
  • physical activity
  • weight loss
  • weight gain
  • high resolution
  • solid phase extraction
  • tandem mass spectrometry