Add to ORKGIron polypyridyl complexes have recently been reported to electrocatalytically reduce protons to hydrogen gas at -1.57 V versus Fc(+)/Fc. A new iron catalyst with a nitro-functionalized polypyridyl ligand has been synthesized and found to be active for proton reduction. Interestingly, catalysis occurs at -1.18 V versus Fc(+)/Fc for the nitro-functionalized complex, resulting in an overpotential of 300 mV. Additionally, the complex is active with a turnover frequency of 550 s(-1). Catalysis is also observed in the presence of water with a 12% enhancement in activity. (C) 2015 Elsevier Ltd. All rights reserved
AbstractEarth-abundant Transition Metal Complexes for Catalytic Proton and Carbon Dioxide ReductionB...
Oil, coal, and natural gas provided the energy that propelled humankind into modern prosperity. Howe...
The demand for energy consumption has increased exponentially since the Industrial Revolution. The m...
Iron polypyridyl complexes have recently been reported to electrocatalytically reduce protons to hyd...
Artificial photosynthesis systems convert solar energy into chemical fuels such as hydrogen gas. Ph...
Iron complexes containing tetradentate monophenolate ligands have been found to be highly active for...
In previous studies, a series of iron(III) complexes containing polypyridyl ligands have been found ...
Increasing global energy demands have led to renewed interest in alternative energy sources such as ...
A family of highly active iron polypyridyl complexes are reported due to their highly active and sta...
Light-driven water splitting for hydrogen generation represents a compelling pathway for carbon-neut...
Climate change, rising global energy demand, and energy security concerns motivate research into alt...
One of the key challenges of modern chemistry is to couple renewable energy sources, such as sunligh...
Concerns over increasing global energy demands, finite fossil fuel reserves, and climate change have...
Artificial Photosynthesis (AP) focuses on developing methods for the conversion of solar energy into...
A series of Fe(III) complexes were recently reported that are stable and active electrocatalysts fo...
AbstractEarth-abundant Transition Metal Complexes for Catalytic Proton and Carbon Dioxide ReductionB...
Oil, coal, and natural gas provided the energy that propelled humankind into modern prosperity. Howe...
The demand for energy consumption has increased exponentially since the Industrial Revolution. The m...
Iron polypyridyl complexes have recently been reported to electrocatalytically reduce protons to hyd...
Artificial photosynthesis systems convert solar energy into chemical fuels such as hydrogen gas. Ph...
Iron complexes containing tetradentate monophenolate ligands have been found to be highly active for...
In previous studies, a series of iron(III) complexes containing polypyridyl ligands have been found ...
Increasing global energy demands have led to renewed interest in alternative energy sources such as ...
A family of highly active iron polypyridyl complexes are reported due to their highly active and sta...
Light-driven water splitting for hydrogen generation represents a compelling pathway for carbon-neut...
Climate change, rising global energy demand, and energy security concerns motivate research into alt...
One of the key challenges of modern chemistry is to couple renewable energy sources, such as sunligh...
Concerns over increasing global energy demands, finite fossil fuel reserves, and climate change have...
Artificial Photosynthesis (AP) focuses on developing methods for the conversion of solar energy into...
A series of Fe(III) complexes were recently reported that are stable and active electrocatalysts fo...
AbstractEarth-abundant Transition Metal Complexes for Catalytic Proton and Carbon Dioxide ReductionB...
Oil, coal, and natural gas provided the energy that propelled humankind into modern prosperity. Howe...
The demand for energy consumption has increased exponentially since the Industrial Revolution. The m...