The mechanism of hydrogen donation by bio-acids over metal supported on nitrogen-doped carbon nanotubes

Engineering & Materials Science

• Molybdenum 82%
• Carbon nanotubes 74%
• Nitrogen 65%
• Acids 64%
• Catalysts 59%
• Hydrogen 56%
• Carboxylic acids 53%
• Transition metals 52%
• Metals 45%
• Energy barriers 27%
• Density functional theory 26%
• Formic acid 26%
• Dehydrogenation 24%
• Precious metals 23%
• Acetic acid 23%
• Hydrogenation 22%
• Doping (additives) 19%
• Molecules 17%
• Biomass 16%
• Decomposition 12%
• Gases 10%
• Costs 6%

Physics & Astronomy

• molybdenum 70%
• catalysts 65%
• acids 63%
• carbon nanotubes 60%
• nitrogen 51%
• carboxylic acids 50%
• hydrogen 43%
• metals 36%
• transition metals 29%
• formic acid 25%
• acetic acid 23%
• biomass 22%
• dehydrogenation 22%
• economy 22%
• noble metals 19%
• hydrogenation 19%
• cleavage 18%
• density functional theory 13%
• decomposition 13%
• molecules 9%
• gases 9%
• performance 7%
• energy 5%

Chemistry

• Nitrogen-Doped Carbon Nanotube 100%
• Hydrogen 35%
• Metal 31%
• Nanotube 28%
• Carboxylic Acid 27%
• Transition Element 25%
• Noble Metal 16%
• Energy Barrier 16%
• Dehydrogenation 16%
• Formic Acid 15%
• Catalyst 14%
• Acetic Acid 13%
• Hydrogenation 13%
• Carbon Nanotube 12%
• Green 12%
• Cleavage 12%
• Decomposition 11%
• Density Functional Theory 10%
• Nitrogen 10%
• Gas 9%
• Molecule 6%