The Internet Archive discovers and captures web pages through many different web crawls.
At any given time several distinct crawls are running, some for months, and some every day or longer.
View the web archive through the Wayback Machine.
This collection contains web crawls performed as the post-inauguration crawl for part of the End of Term Web Archive, a collaborative project that aims to preserve the U.S. federal government web presence at each change of administration. Content includes publicly-accessible government websites hosted on .gov, .mil, and relevant non-.gov domains, as well as government social media materials. The web archiving was performed in the Winter of 2016 and Spring of 2017 to capture websites after the January 20, 2017 inauguration. For more information, see http://eotarchive.cdlib.org/.
We conduct research and development (R&D) in solar power, including photovoltaics and concentrating solar power, to strengthen the U.S. solar industry and improve the manufacturability, reliability, and cost competitiveness of solar energy technologies and systems.
Use microdesign and microfabrication techniques to produce miniaturized solar cells that are released into a solution similar to printing ink.
Sandia Labs’ solar photovoltaic (PV) work is focused on developing cost-effective, reliable photovoltaic energy systems and accelerating the integration of PV technology in the United States and globally. The Labs’ PV department provides the technical lead for systems integration and balance-of-systems manufacturing technologies as well as technical support to the U.S. Department of Energy (DOE) in deployment and validation of PV systems for federal agencies, utilities, and other institutional users. Sandia assists industry and users by providing technical assistance, accurate performance measurements, component development and improvement, and system evaluation. A major thrust of the department is to evaluate and improve the performance, reliability, and cost effectiveness of systems and balance-of-systems components.
Sandia’s PV research staff work collaboratively with DOE’s Solar Energy Technologies Program, the U.S. photovoltaic industry, other government agencies and national laboratories, and international organizations to increase the worldwide use of PV power systems by reducing cost, improving reliability, increasing performance, removing barriers, and growing markets.
Supporting the development and improvement of solar PV technologies, and providing skilled testing and evaluation of all PV components, including cells, modules, inverters, and balance of system components.
Concentrating Solar Power (CSP)
Concentrating Solar Power (CSP) uses mirrors to concentrate a large area of sunlight, onto a small area. Electrical power is produced when the concentrated light is converted to heat which drives a generator.
In virtually all applications CSP is large power, on the order of 100 MW or larger, that is used by utilities to generate electricity and distribute to consumers. In a CSP plant, solar energy is converted to heat and the heat is used in a conventional power cycle or other heat engine to produce mechanical power and drive a generator.
This unique facility provides experimental engineering data for the design, construction, and operation of unique components and systems in proposed solar thermal electrical plants; planned for large-scale power generation. At 200 feet tall, the NSTTF’s distinct height advantage along with its heat capabilities, offers a unique and complete testing environment to government contractors and agencies, research institutes, universities and private companies.
MEPV concepts use microdesign and microfabrication techniques to produce miniaturized solar cells that are released into a solution similar to printing ink. This solution is then placed or ‘printed’ onto a low-cost substrate with embedded contacts and microlenses for focusing sunlight onto the cells. Sandia’s approach uses cells that are tiny in both thickness and lateral dimensions – as small as 14 microns thick and 250 microns wide. The thinness of the cells reduces material costs while enhancing cell performance by improving carrier collection and potentially achieving higher open circuit voltages.
ASME Journal of Solar Energy Engineering Special Issue: Photovoltaic Tracking Technology Photovoltaic (PV) energy systems are becoming a larger share of electricity production, with over 230 GW installed worldwide. Much of this growth is being driven [...]
In order to accelerate solar module materials discovery and development, the DOE SunShot program awarded $30 million, over five years, to a national laboratory-led Energy Materials Network (EMN) Consortium focused on durable module materials, DuraMat. Module [...]
We are looking for a dynamic individual with a passion for solar energy R&D to lead our Department and Programs. The National Solar Thermal Test Facility in Albuquerque, NM is the only facility of its [...]
Expert Workshop in Freiburg: Modeling and Monitoring of PV Systems The Fraunhofer Institute for Solar Energy Systems ISE is acting as host for this year’s “PV Performance Modeling and Monitoring Workshop”. Photovoltaics experts from around [...]