Hydrogen research earns $5.1 million in Global Climate and Energy Project grants.Energy Editors/News Editors/Education Writers STANFORD, Calif.--(BUSINESS WIRE)--Nov. 18, 2003 The Global Climate and Energy Project The Global Climate and Energy Project (GCEP) at Stanford University "seeks new solutions to one of the grand challenges of this century: supplying energy to meet the changing needs of a growing world population in a way that protects the environment. (GCEP GCEP Global Change Education Program GCEP Gas Centrifuge Enrichment Plant GCEP Georgia College of Emergency Physicians ) has awarded four projects a total of $5.1 million to research the use of hydrogen as an energy carrier. Stanford faculty from a range of disciplines will lead the individual research efforts, and the projects will be funded over a three-year period beginning January 2004. "Our faculty responded quickly with good proposals to the challenge we offered: Propose research that, if successful, would help enable creation of energy systems with low emissions of greenhouse gases," said GCEP Director Lynn Orr. Launched at Stanford in December 2002, GCEP is a long-term collaborative effort between the scientific and engineering community at research institutions and private industry. Its purpose is to conduct fundamental, pre-commercial research that would foster the development of a global energy system with significantly lower greenhouse emissions. With funding of $225 million from its sponsors, GCEP has begun to investigate a spectrum of research areas for our energy future. Hydrogen offers the potential to be a virtually pollution-free fuel since it produces only water when used in engines, fuel cells or other energy systems. However, many questions remain regarding possible greenhouse gas emissions from the production of hydrogen fuel. Moreover, the safe and effective storage and use of hydrogen, as well as the costs of the required technologies and the associated infrastructure, need to be examined further. The four new projects include: -- "Nanoengineering of Hybrid Carbon Nanotube See nanotube. -- Metal Nanocluster Composite Materials for Hydrogen Storage
Hydrogen storage is the main technological problem of a viable hydrogen economy. Some attention has been given to the role of hydrogen to provide grid energy storage for unpredictable energy sources, like " led by Kyeongjae "K. J." Cho of Mechanical Engineering, Bruce Clemens of Materials Science and Engineering Materials science and engineering A multidisciplinary field concerned with the generation and application of knowledge relating to the composition, structure, and processing of materials to their properties and uses. , Hongjie Dai Professor Hongjie Dai of the Department of Chemistry at Stanford University is a leading figure in the study of carbon nanotubes. Born in China in 1966, he received a B.S. in Physics from TsingHua University, Beijing, in Physics in 1989 and a Ph.D. of Chemistry and Anders Nilsson of the Stanford Synchrotron synchrotron: see particle accelerator. synchrotron Cyclic particle accelerator in which the particle is confined to its orbit by a magnetic field. The strength of the magnetic field increases as the particle's momentum increases. Radiation Laboratory -- awarded $2,250,000. -- "Hydrogen Effects on Climate, Stratospheric strat·o·spher·ic adj. 1. Of, relating to, or characteristic of the stratosphere. 2. Extremely or unreasonably high: "money borrowed at today's stratospheric rates of interest" Ozone and Air Pollution" led by Mark Z. Jacobson of Civil and Environmental Engineering and David M. Golden of Mechanical Engineering -- awarded $797,125. -- "Solid-State NMR NMR: see magnetic resonance. Studies of Oxide Ion Conducting Ceramics for Enhanced Fuel Cell Performance" led by Jonathan Stebbins of Geological and Environmental Sciences -- awarded $1,133,476. -- "Nanostructured Photovoltaic Cells" led by Mike McGehee of Materials Science and Engineering -- awarded $897,207. "I am extremely excited to be a part of this GCEP project and to have an opportunity to help solve one of the world`s most important problems," said McGehee, one of the award recipients. "The level of funding will enable my research team to take a very aggressive approach toward electrolytically generating hydrogen with new low-cost solar cells." In June of this year, GCEP requested proposals from Stanford faculty and was particularly interested in approaches or technologies that are high-risk/high-reward in the area of hydrogen production Hydrogen production is commonly completed from hydrocarbon fossil fuels via a chemical path. Hydrogen may also be extracted from water via biological production in an algae bioreactor, or using electricity (by electrolysis) or heat (by thermolysis); these methods are presently not , storage and use. Eight proposals were received and sent out for external, independent reviews -- first by specialists in the technical areas of each proposal, then by experts in the overall field of hydrogen. The panel of hydrogen experts ranked the projects in terms of their scientific quality and their relevance to GCEP`s goal of a low-greenhouse-gas future. After detailed discussions about each proposal, the panel members and GCEP central staff came to a consensus on which ones were strongest, and a slate of four projects was recommended for funding. "A large group of thorough external reviewers worked hard to complete the review process much more quickly than is common in other competitions for funding," Orr said. The slate of hydrogen-related projects was then approved by the GCEP Management Committee, which includes representatives of the project`s sponsors -- ExxonMobil, GE, Schlumberger and Toyota. "I`m glad that I will be surrounded by other researchers with a wide variety of expertise who will be looking at ways to generate, store, transport and use hydrogen," McGehee said. "I think that together the GCEP teams have a great chance of making hydrogen a viable source of fuel." The GCEP committee members noted that important aspects of the approved projects could affect other areas -- beyond hydrogen -- of the broad GCEP research portfolio. The project is conducting assessments in other areas including renewable energy Renewable energy utilizes natural resources such as sunlight, wind, tides and geothermal heat, which are naturally replenished. Renewable energy technologies range from solar power, wind power, and hydroelectricity to biomass and biofuels for transportation. , carbon capture and storage Carbon capture and storage (CCS) is an approach to mitigating global warming by capturing carbon dioxide (CO2) from large point sources such as power plants and subsequently storing it instead of releasing it into the atmosphere. , and advanced materials Advanced Materials is a leading peer-reviewed materials science journal published every two weeks. Advanced Materials includes Communications, Reviews, and Feature Articles from the cutting edge of materials science, including topics in chemistry, physics, . In the future, it will sponsor additional research at Stanford and other universities and institutions. Relevant Web URLs: Global Climate and Energy Project http://gcep.stanford.edu Maxine Lym is communications manager for the Global Climate and Energy Project. By Maxine Lym |
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