Carborane-Based Metal-Organic Framework with High Methane and Hydrogen Storage Capacities

A Cu-carborane-based metal organic framework (MOF), NU-135, which contains a quasi-spherical para-carborane moiety, has been synthesized and characterized. NU-135 exhibits a pore volume of 1.02 cm(3)/g and a gravimetric BET surface area of ca. 2600 m(2)/g, and thus represents the first highly porous...

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Veröffentlicht in:	Chemistry of materials 2013-09, Vol.25 (17)
Hauptverfasser:	Kennedy, RD, Krungleviciute, V, Clingerman, DJ, Mondloch, JE, Peng, Y, Wilmer, CE, Sarjeant, AA, Snurr, RQ, Hupp, JT, Yildirim, T, Farha, OK, Mirkin, CA
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container_title	Chemistry of materials
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creator	Kennedy, RD Krungleviciute, V Clingerman, DJ Mondloch, JE Peng, Y Wilmer, CE Sarjeant, AA Snurr, RQ Hupp, JT Yildirim, T Farha, OK Mirkin, CA
description	A Cu-carborane-based metal organic framework (MOF), NU-135, which contains a quasi-spherical para-carborane moiety, has been synthesized and characterized. NU-135 exhibits a pore volume of 1.02 cm(3)/g and a gravimetric BET surface area of ca. 2600 m(2)/g, and thus represents the first highly porous carborane-based MOF. As a consequence of the, unique geometry of the carborane unit, NU-135 has a very high volumetric BET surface area of ca. 1900 m(2)/cm(3). CH4, CO2, and H-2 adsorption isotherms were measured over a broad range of pressures and temperatures and are in good agreement with computational predictions. The methane storage capacity of NU-135 at 35 bar and 298 K is ca. 187 v(STP)/v. At 298 K, the pressure required to achieve a methane storage density comparable to that of a compressed natural gas (CNG) tank pressurized to 212 bar, which is a typical storage pressure, is only 65 bar. The methane working capacity (5-65 bar) is 170 v(STP)/v. The volumetric hydrogen storage capacity at 55 bar and 77 K is 49 g/L. These properties are comparable to those of current record holders in the area of methane and hydrogen storage. This initial example lays the groundwork for carborane-based materials with high surface areas.
doi_str_mv	10.1021/cm4020942
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title	Carborane-Based Metal-Organic Framework with High Methane and Hydrogen Storage Capacities
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