ÁùºÏ±¦µä has all of the resources — sun, wind, geothermal, biomass — to become one of the nation’s leaders in renewable energy.
But before the state’s great natural resource gifts can be realized, however, someone must take the lead in organizing this vast array of natural resource riches.
The University of ÁùºÏ±¦µä, Reno, is quickly filling this leadership role with a number of initiatives that promise to transform not only the economy of the state of ÁùºÏ±¦µä but to revitalize and revamp the national economy with the creation of new companies, new jobs and an entirely new emphasis on renewable energy and a much-needed investment in the rebuilding of the nation’s infrastructure.
According to Manos Maragakis, dean of the College of Engineering, the University has undertaken this role because it is uniquely suited, with talented researchers in all the key renewable energy areas. Their combined talented promise to bring the diverse elements of a modern 21st-century economy together in ways that could change ÁùºÏ±¦µä forever.
Maragakis describes the University as “the hub, the center” of this effort.
“What is important to remember is that for many areas of the country, these ideas are in their infancy or have many years of creating a solid research foundation before they are ever even realized,” Maragakis said. “At ÁùºÏ±¦µä, we are unique in that we have already started much of this work. All of these things are happening on our campus, right now — this is not only in research and development, but in education, with a number of new majors and minors that the University offers in these highly strategic areas.”
Just one example is the recently announced Renewable Energy Center, where the focus will be on synchronizing programs for competitive research in renewable energy.
“The University is a leader in renewable energy education in ÁùºÏ±¦µä, and through this collaborative we can work to make ÁùºÏ±¦µä a powerhouse in renewable energy in the entire country,” said Manoranjan Misra, a professor of materials science and engineering in the College of Engineering. “We have research on hydrogen fuels, bio-diesel, plants to biofuel, geothermal and the many subcategories and components of these types of renewable power. We will continue to work to bring together education and industry to develop these systems here in ÁùºÏ±¦µä, boosting the economy with jobs as well as sales of products and services.”
All Misra has to do to reinforce this point is to simply look out the window of his office in the Laxalt Mineral Engineering Building on the University campus.
Northern ÁùºÏ±¦µä’s uncommonly sunny skies are easy to see.
“Talk about the perfect natural resource,” Misra, one the campus’ most gifted researchers, says. “The sun is almost always shining in northern ÁùºÏ±¦µä.”
Misra, working with a $3 million research grant from the U.S. Department of Energy, has found a groundbreaking, highly effective way of harnessing photoactive material from the sun to generate hydrogen. The catalytic process produces inexpensive hydrogen from geothermal water and takes advantage of a plentiful northern ÁùºÏ±¦µä resource. Misra’s renewable energy research portfolio is extensive, with more than $10 million in funding for various renewable projects.
Hydrogen, one of the cleanest forms of energy, is more efficient than liquid fuels, and could hold one of the keys to ÁùºÏ±¦µä’s future in becoming a national leader in renewable energy.
Misra envisions a day in the not-so-distant future when ÁùºÏ±¦µä — with more than 300 days of sunny weather per year — will become the perfect hub to generate hydrogen energy, producing low-cost, no-impact fuel for automobiles and energy for homes and businesses.
“We can utilize this great energy resource from the sun to our advantage to produce hydrogen,” Misra says. “We are uniquely positioned in ÁùºÏ±¦µä because of this. Given the weather in northern ÁùºÏ±¦µä, where on most days we have 10 to 15 percent more sunlight than in other areas of the country, the future of this type of energy is limitless.”
Misra’s work is just one of many examples of cutting-edge research and education being conducted on the campus of the University of ÁùºÏ±¦µä.
The University has made impressive inroads in renewable energy curriculum with the addition of a Renewable Energy Minor in 2007. The new collaborative effort promises to create even more educational synergy through the coordinated efforts of faculty in four colleges within the University: the College of Agriculture, Biotechnology and Natural Resources; College of Business; College of Engineering; College of Science. Activities will be overlooked by the deans of the various participating colleges, and will also include working groups in key areas such as biomass, geothermal, solar energy, power grid and curriculum, with an additional group focused on business, hydrogen, public policy, outreach and education.
“Ultimately, we can become more community-driven and can use our science to help our community,” Provost Marc Johnson said. “We want to make the University easier to work with for industry and the business community. We want to train students for the increasingly technological workforce and build our capacity for research at the same time.”
“The unifying theme throughout this work lies in the export of our expertise,” Maragakis added. “We have uniquely qualified faculty and we need to give them the opportunity to work together as equal partners without having to worry about administrative barriers and details. I feel that their potential is unlimited.”
ÁùºÏ±¦µä’s expertise stretches to many areas, including:
- ÁùºÏ±¦µä researchers in the College of Engineering, led by Amy Childress, professor and chair of the Department of Civil and Environmental Engineering, have created novel methods using osmosis and forward osmosis to treat wastewater for potable reuse or for power regeneration. The method not only reduces the footprint of current power regimes, it could also revolutionize how large municipalities in the country effectively optimize their use of water as a power source.
- The Center for Civil Engineering Earthquake Research is home to some of the nation’s most important large-scale structures laboratory and a unique world-renowned earthquake simulation facility. Using the largest earthquake shake tables in the nation, numerous earthquake simulations on the bi-axial shake tables have helped improve the design and structural stability of large-scale structures throughout the country. The structures group, led by Ian Buckle, is already leading infrastructure and earthquake mitigation research across the nation. Their efforts are complemented by a cadre of talented seismology scientists in the College of Science that specializes in the study of earthquakes.
- Misra, of the Chemical and Metallurgical Engineering Department, has developed a novel process — believed to be the first of its kind in the country — to extract biodiesel from spent coffee grounds. The process has important implications in the world’s efforts to combat global warming through the creation of alternative fuels such as biodiesel while utilizing an inexpensive waste product. Misra’s work on coffee biodiesel has received world-wide attention. Misra and his group are working on a novel process to convert carbon dioxide to gasoline. In the not-so-distant future Misra envisions a day where the United States will run cars with fuels from carbon dioxide.
- The Western Regional Superpave Center, under the direction of Peter Sabaaly of the Civil and Environmental Engineering Department, is one of the nation’s leaders in promoting the implementation of pavement and asphalt technologies. Researchers have evaluated the tolerance of different paving materials for roads in areas that are prone to extremes in temperature, and provide high-tech, low-cost solutions to paving projects throughout the state and the nation.
- Kwang Kim, professor and chair of the Department of Mechanical Engineering, has pioneered heat transfer enhancement techniques in condensers for use in geothermal power plants, as well as thermal compression of hydrogen utilizing geothermal energy. Kim’s research is helping close the gap between the possibility and the reality of making geothermal energy less costly and more viable for the nation.
- At the Great Basin Center for Geothermal Energy, led by Lisa Shevenell, ÁùºÏ±¦µä researchers are collecting and synthesizing key data through GIS technology in an effort to produce favorability maps of the state’s geothermal potential.
- At the Redfield Renewable Energy Center on the University’s Redfield Campus, classrooms and research space are being utilized in teaching undergraduate and graduate students about renewable energy through the University’s new renewable energy minor.
- Researchers in the College of Agriculture, Biotechnology and Natural Resources are at the forefront in the next key evolution in biofuels and their use in ÁùºÏ±¦µä. In the laboratory of John Cushman, professor of biochemistry, microalgae has been developed for biodiesel feedstock, as a sequester of carbon dioxide from coal and gas-fired power plants, and as a way to produce biomass, which can be used for heating pellets.
- In addition to these projects, ÁùºÏ±¦µä researchers continue to work closely with the faculty of its ÁùºÏ±¦µä System of Higher Education partners, the Desert Research Institute (DRI), and the University of ÁùºÏ±¦µä, Las Vegas (UNLV). DRI has national and worldwide expertise in such key areas as hydrology, atmospheric science and renewable energy. Of particular note, DRI’s Renewable Energy Center has ongoing projects focused on wind energy, hydrogen application and bioenergy.
“These are the tips of the iceberg,” Maragakis said. “It’s not just the College of Engineering … or the College of Agriculture, Biotechnology and Natural Resources … or the College of Science … or the College of Business. It really is the whole University uniting in this effort.”
Taken together, the work is creating a critical mass of knowledge in the energy and infrastructure economies of the nation that could give the state a strategic edge in the competition for jobs and businesses.
Lawrence Lieberman, a former Dean of Admissions for the Stanford Business School and a member of the Advisory Board for the College of Engineering, said he believes that the University’s “core competencies” in these areas can create “unfair advantages” for the institution.
They are “unfair advantages” that could catapult University to the forefront of a new economy.
“The state desperately needs to diversify its economic base, and we have the potential to be a leader in renewable energy, and in rebuilding our nation’s bridges and roads,” he said. “There is such great stuff that is going on at the University. The University has extraordinary expertise and in some areas has core competencies that few other areas in the country can claim. The focus of the research and development efforts are directly in line with what President Obama is trying to accomplish with the stimulus plan.
“Right now there seems to be a real increase in demand for expertise, and this in turn can create more jobs — white-collar, clean jobs that basically bring money back into our state.”
Misra, who has spent a distinguished career spanning more than 25 years in developing alternative fuel source technologies, said it’s an exciting time to be a researcher at the University.
“We can lead the nation,” he said. “People often say, ‘Why ÁùºÏ±¦µä?’ Well, ‘why not ÁùºÏ±¦µä.’ The timing to become the nation’s leader in finding alternative ways of fueling our cars or heating our homes or powering our computers has never been any better than right now.”
(Editor’s note: story contains reporting from Mike Wolterbeek, media relations officer in University Media Relations.)