Materials Challenges for Sustainable
Photoelectrochemical Solar to Fuel Conversion J. W. Ager
Development of Efficient, Stable and Intrinsically Safe
Photoelectrochemical Solar - Hydrogen Prototypes C. Xiang
Not exact matches
Nonetheless, this dramatic increase in quantum yield realized with a uniquely innovative lead sulfide quantum dot
photoelectrochemical device is an important development in several ways, and as such is a product of Yan's long - standing interest in renewable sources of energy, especially in novel applications of
solar energy.
The new approach relies on a
photoelectrochemical (PEC) device, a type of
solar cell that can potentially split water molecules more efficiently than other methods.
The HydroGEN program encompasses advanced electrolytic,
photoelectrochemical, and
solar thermochemical hydrogen production processes.
(Invited) High Performance Components for
Solar - Driven
Photoelectrochemical Fuel Generators.
Shown is a
photoelectrochemical cell illuminated by a
solar simulator.
(Invited) Recent Progress in Fundamental
Photoelectrochemical Studies Relevant to New Low - Cost Designs for Z - Scheme
Solar Water Splitting Reactors.
Part 1:
Photoelectrochemical (PEC) Water Splitting Thursday, November 10, 2016 4 — 5 p.m. EST Part 2: Electrolysis Tuesday, November 15, 2016 4 — 5 p.m. EST Part 3:
Solar Thermochemical (STCH) Hydrogen Production Thursday, November 17, 2016 4 — 5 p.m. EST
The technologies include advanced high - and low - temperature electrolysis as well as
photoelectrochemical (PEC) and
solar thermochemical (STCH) water splitting.
Multiple technologies will be explored within the HydroGEN program including advanced electrolysis,
photoelectrochemical processes, and
solar thermochemical hydrogen production.
Li, J. T. & Wu, N. Q. Semiconductor - based photocatalysts and
photoelectrochemical cells for
solar fuel generation: a review.
Shown is a
photoelectrochemical cell illuminated by a
solar simulator.
A key objective of work in the program is to develop a knowledge foundation of structure - function relationships for
photoelectrochemical layers that allows for prediction and control of transport phenomena in macroscopic
solar - fuel generation systems.
Hydrogen, which is the simplest form of energy carrier, can be generated renewably with
solar energy through
photoelectrochemical water splitting or by photovoltaic (PV)-- driven electrolysis.
Scientists at the US Department of Energy's (DOE) National Renewable Energy Laboratory (NREL) recaptured the record for highest efficiency in
solar hydrogen production via a
photoelectrochemical (PEC) water - splitting process.