Experienced research and development professional motivated to strategically solve difficult technical problems to advance electrochemical and
photoelectrochemical energy conversion and storage technologies (fuel cells, supercapacitors, redox flow batteries, metal - air batteries, and photoelectrochemical cells) and deliver meaningful results for the betterment of our society.
Ian Sharp, «Plasma - enhanced Atomic Layer Deposition of Transition Metal Oxides for
Photoelectrochemical Energy Conversion»
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 article, «Multiple exciton generation for
photoelectrochemical hydrogen evolution reactions with quantum yields exceeding 100 %,» reports on the investigative work that Yan carried out along with colleagues affiliated with the National Renewable
Energy Laboratory, the Colorado School of Mines and San Diego State University.
Several promising earth - abundant low band - gap TMO compounds with desirable band edge
energies and electrochemical stability are identified by our computational efforts and then synergistically evaluated using high - throughput synthesis and
photoelectrochemical screening techniques by our experimental collaborators at Caltech.
After moving to Lawrence Livermore National Laboratory, he has been working on scientific problems that are relevant for
energy storage and conversion technologies such as
photoelectrochemical (PEC) hydrogen production.
This career has included tenures at the Oak Ridge National Laboratory, Sunpower Incorporated, the NASA Glenn Research Center, and the Hawai'i Natural
Energy Institute, where his pioneering research in the field of
photoelectrochemical hydrogen production has earned world recognition.
A 2013 book on
photoelectrochemical (PEC) water splitting developed by the U.S. Department of
Energy's (DOE's) PEC hydrogen production working group was one of the top 25 % most downloaded eBooks in the SpringerLink eBook Collection in 2016.
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.
Researchers at the
Energy Department's National Renewable
Energy Laboratory (NREL) have made advances toward affordable
photoelectrochemical (PEC) production of hydrogen.
Researchers at the US Department of
Energy's National Renewable
Energy Laboratory (NREL) have developed a method which boosts the longevity of high - efficiency photocathodes in
photoelectrochemical water - splitting devices.
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.