11 research outputs found
Particle suspension reactors and materials for solar-driven water splitting
Reactors based on particle suspensions for the capture, conversion, storage, and use of solar energy as H_2 are projected to be cost-competitive with fossil fuels. In light of this, this review paper summarizes state-of-the-art particle light absorbers and cocatalysts as suspensions (photocatalysts) that demonstrate visible-light-driven water splitting on the laboratory scale. Also presented are reactor descriptions, theoretical considerations particular to particle suspension reactors, and efficiency and performance characterization metrics. Opportunities for targeted research, analysis, and development of reactor designs are highlighted
Recommended from our members
Control of the Hydrogen Evolution Reaction on Metal Oxides for Energy Storage
Hydrogen can be used as a replacement for fossil fuels in many applications. However,commercially relevant scales of hydrogen production utilize either electrolysis or a combination of steam methane reforming and the water gas shift reaction which are energy intensive and non-renewable. Here I report on a portion of work toward understanding the fundamental physical and chemical phenomena that constrain the maximum solar-to-hydrogen (STH) conversion efficiency for photoelectrochemical particle-slurry reactors. Using Rh-doped strontium titanate (SrTiO 3 :Rh), a variable power light source, and an inline-mass spectrometry the rate of hydrogen production can be controlled and optimized.In the second part of my work, I report on the spectro-electrochemical behavior of crystalline titanium dioxide (TiO2) mesoporous films as a model system for aqueous redox flow battery charging/discharging. The effects of potential determining ions on the density of states in the materials are discussed
Recommended from our members
Control of the Hydrogen Evolution Reaction on Metal Oxides for Energy Storage
Hydrogen can be used as a replacement for fossil fuels in many applications. However,commercially relevant scales of hydrogen production utilize either electrolysis or a combination of steam methane reforming and the water gas shift reaction which are energy intensive and non-renewable. Here I report on a portion of work toward understanding the fundamental physical and chemical phenomena that constrain the maximum solar-to-hydrogen (STH) conversion efficiency for photoelectrochemical particle-slurry reactors. Using Rh-doped strontium titanate (SrTiO 3 :Rh), a variable power light source, and an inline-mass spectrometry the rate of hydrogen production can be controlled and optimized.In the second part of my work, I report on the spectro-electrochemical behavior of crystalline titanium dioxide (TiO2) mesoporous films as a model system for aqueous redox flow battery charging/discharging. The effects of potential determining ions on the density of states in the materials are discussed
TechKNOW Volume 16, Issue 2
https://kent-islandora.s3.us-east-2.amazonaws.com/techknow/2/thumbnail.jp
TechKNOW Volume 3, Issue 1
https://kent-islandora.s3.us-east-2.amazonaws.com/techknow/41/thumbnail.jp
TechKNOW Volume 1, Issue 3
https://kent-islandora.s3.us-east-2.amazonaws.com/techknow/50/thumbnail.jp
TechKNOW Volume 14, Issue 2
https://kent-islandora.s3.us-east-2.amazonaws.com/techknow/6/thumbnail.jp
TechKNOW Volume 16, Issue 1
https://kent-islandora.s3.us-east-2.amazonaws.com/techknow/1/thumbnail.jp