News and analysis on materials solutions to energy challenges
- PDF / 347,222 Bytes
- 1 Pages / 585 x 783 pts Page_size
- 7 Downloads / 170 Views
Inside:
EDITORIAL
Energy technologies united ENERGY SECTOR ANALYSIS
Solid-state batteries enter EV fray ENERGY SECTOR ANALYSIS
Cement performance impacts integrity of oil and gas wells
ENERGY QUARTERLY ORGANIZERS CHAIR M. Stanley Whittingham, State University of New York at Binghamton, USA Anshu Bharadwaj, Center for Study of Science, Technology and Policy, India David Cahen, Weizmann Institute, Israel Russell R. Chianelli, The University of Texas at El Paso, USA George Crabtree, Argonne National Laboratory, USA Sabrina Sartori, University of Oslo, Norway Anke Weidenkaff, University of Stuttgart, Germany Steve M. Yalisove, University of Michigan, USA
MATERIALS FOR ENERGY BLOG
www.materialsforenergy.org Hosted by the MRS University Chapter of The University of Texas at Austin
Images incorporated to create the energy puzzle concept used under license from Shutterstock.com. Energy Sector Analysis image: Cross-section of a wellbore. Credit: US Department of Energy's National Energy Technology Laboratory.
To suggest ideas for ENERGY QUARTERLY, to get involved, or for information on sponsorship, send email to [email protected].
Energy technologies united The shortage of energy will be one of the main societal challenges for our future. While renewable energy sources exist (sun, wind, tides) in addition and as alternatives to fossil fuels, we are still learning how to harvest this energy and to economically and viably transform it into useful power. For this, the role of materials researchers is crucial for improving materials performance for enabling renewable and sustainable energy technologies. Unified strategies are needed for making our efforts successful. The sun, for example, has great potential as an enormous energy reservoir, if only we could exploit it properly. But sun exposure is discontinuous and site-dependent, which results in an intermittent and unpredictable power availability. The same applies to wind, the other major source of renewable energy besides hydro. Energy saving achieved by more efficiently utilizing conventional fuels should also be considered. Fuel cells provide a highly efficient method for producing power, and solidoxide fuel cells can, in principle, operate at higher temperatures with a wide range of fuels, including hydrocarbons. The attainable increase in efficiency may guarantee a significant cut in greenhouse emissions in the medium term, while we wait for the infrastructure of hydrogen storage and distribution to be in place. However, fuel cells supply power continuously, while demand can vary over time. The problems of intermittent or continuous supply and variable demand need to be addressed and solved by leveraging continuous energy supply, which has to be achieved by the integration of different energy-storage systems (batteries, supercapacitors, electrolyzers), either by compensating for the lack of power from renewable sources or for excess power produced by fuel cells when not needed. We as materials researchers cannot solve the energy problems by develop
Data Loading...
