The LLNL team has developed unique
capabilities for the characterization of electrochemical systems for more than 15 years [1]; furthermore, they have ~ 20 years» experience in the use of XAS / XES to determine information critical to the performance of photoabsorber materials, particularly in the arena of photovoltaics.
Tip - enhanced optical spectroscopies (TEOS) such as TERS (tip - enhanced Raman spectroscopy) and TEPL (tip - enhanced photoluminescence) provide a unique
capability for the characterization of diverse 0, 1 and 2D materials.
Not exact matches
«This approach provides additional rapid
characterization capability for emergency responders to radiological events, enabling further optimization of limited resources,» Hayes says.
Capabilities for catalyst synthesis and
characterization can lead to the advancement of thermochemical water splitting cycles.
This work has extended to the establishment of
capabilities in
characterization to preclude exposure of specimens to reactive environments through bulk electropolishing and specimen transfer via portable glove box systems
for detailed electron backscattering diffraction (EBSD) analyses, which are highly dependent upon specimen surface quality.
In addition to providing fabrication,
characterization, and testing
capabilities, the NNI's physical infrastructure also provides a place
for researchers, industry, and ideas to mix, further expanding the community.
The HTE
capabilities include combinatorial synthesis, spatially - resolved
characterization, and semi-automated data analysis
for thin film materials (see Figure below).
In addition, the understanding from the extensive computational
capabilities in this area, coupled to the extensive experimental and
characterization capabilities, can rapidly accelerate the optimization of materials
for this application.
Our
capability consists of design, fabrication, and
characterization of large area Al based nanopatterned electrodes
for plasmon enhanced photoelectrochemistry (PEC).
It admittedly allows
for better pacing, but the
capability of the actors feels squandered in favor of thinner
characterization.
JCAP will capitalize on advanced
capabilities developed during its initial five years of research, including sophisticated
characterization tools and unique automated high - throughput experimentation that can quickly make and screen large libraries of materials to identify components
for artificial photosynthesis systems.
While the scientific challenges of producing such fuels are considerable, JCAP will capitalize on state - of - the - art
capabilities developed during its initial five years of research, including sophisticated
characterization tools and unique automated high - throughput experimentation that can quickly make and screen large libraries of materials to identify components
for artificial photosynthesis systems.
PROFESSIONAL EXPERIENCE Process / Equipment Engineer — OmniPV, Inc., Menlo Park, CA 2008 — 2011 Collaborated on development of photoluminescent semiconductor material used
for third generation solar module, with
capability to reduce cost of solar energy to under $ 0.25 / W. Designed and built laboratory
for thin film deposition and
characterization, purchased equipment worth more than $ 250K from various vendors, successfully negotiated contracts with various vendors and service providers to have laboratory and processes running uninhibited.