Nanoconfinement and catalytic dehydrogenation of ammonia borane by magnesium-metal-organic-framework-74

Chemistry - A European Journal

Volumn 17, Issue 22, 2011, Pages 6043-6047

  Gadipelli, Srinivas ^a,b   Ford, Jamie ^a,b   Zhou, Wei ^a,c   Wu, Hui ^a,c   Udovic, Terrence J ^a   Yildirim, Taner ^a,b  

^a NATIONAL INSTITUTE OF STANDARDS AND TECHNOLOGY   (United States)

^b UNIVERSITY OF PENNSYLVANIA   (United States)

^c UNIVERSITY OF MARYLAND   (United States)

Author keywords

ammonia borane; dehydrogenation; kinetics; metal organic frameworks; nanoconfinement

Indexed keywords

AIR STABILITY; AMMONIA BORANE; AQUEOUS SOLUTIONS; BORAZINE; BOROHYDRIDES; CANDIDATE MATERIALS; CATALYTIC DEHYDROGENATION; CATALYTIC HYDROLYSIS; DEHYDROGENATION KINETICS; DIBORANE; DIRECT USE; HEAVY METAL CATALYSTS; HYBRID STRUCTURE; HYDROGEN CAPACITIES; HYDROGEN DENSITIES; HYDROGEN ENERGY; HYGROSCOPIC PROPERTIES; LOW MOLECULAR MASS; METAL ORGANIC FRAMEWORK; NANOCONFINEMENTS; NEGATIVE IMPACTS; NONAQUEOUS SOLUTIONS; POROUS SCAFFOLD; RELEASE KINETICS; VOLATILE BY-PRODUCTS; WATER SOLUBILITIES;

AMMONIA; BYPRODUCTS; CATALYSTS; DEHYDROGENATION; DRIERS (MATERIALS); FUEL CELLS; FUEL STORAGE; HEAVY METALS; HYDROGEN; HYDROGEN STORAGE; IONIC LIQUIDS; KINETICS; MAGNESIUM; NANOCOMPOSITES; ORGANIC SOLVENTS; SCAFFOLDS; TRANSITION METALS;

DENSITY OF LIQUIDS;

EID: 79956139186     PISSN: 09476539     EISSN: 15213765     Source Type: Journal    
DOI: 10.1002/chem.201100090     Document Type: Article

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