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4 - Energy cost of materials: materials for thin-film photovoltaics as an example

from Part 1 - Energy and the environment: the global landscape

Published online by Cambridge University Press:  05 June 2012

By
Ajay K. Gupta  and
Charles A. S. Hall
Edited by
David S. Ginley  and
David Cahen
Charles A. S. Hall
Affiliation:
Department of Environmental and Forest Biology and Environmental Sciences, College of Environmental Science and Forestry, State University of New York, Syracuse, NY, USA
David S. Ginley
Affiliation:
National Renewable Energy Laboratory, Colorado
David Cahen
Affiliation:
Weizmann Institute of Science, Israel
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Summary

Focus

Renewable forms of energy are being sought to fulfill future needs in the face of declining fossil-fuel reserves. Much attention is being paid to energy availability, the economy, and the effects that changes in the two might have on daily life. However, little emphasis has been placed on the question of how much energy must be spent to get new sources of energy into the economy in the first place. This chapter examines this question using thin-film photovoltaics as an example.

Synopsis

Prior to the 1740s, only 13 elements in what is now called the periodic table were known to exist. By the twentieth century, all 90 naturally occurring chemical elements had been discovered and put to use in the economy. Industry has found methods of extracting, refining, and using just about every material humans have found on Earth, and this process continues to evolve today as the demands of a continually growing industrial society require ever more complex materials. As much as materials make today's industries possible, they also represent a constraint – because raw materials are needed to produce desired goods and, in turn, energy is required to develop the materials as well. Nowhere is this more important than in the energy production systems that power today's world and those that will power future societies as well.

Type
Chapter
Information
Fundamentals of Materials for Energy and Environmental Sustainability , pp. 48 - 60
Publisher: Cambridge University Press
Print publication year: 2011

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References

Goldemberg, J.Johansson, T. B.Reddy, A. K. N.Williams, R. H. 1985 “Basic needs and much more with one kilowatt per capita,”Ambio 14 190Google Scholar
Blanco, J. M. 1995
UNDP 2004 Reducing Rural Poverty Through Increased Access to Energy Services: A Review of the Multifunctional Platform Project in MaliUNDP Mali OfficeGoogle Scholar
SPREE School of Photovoltaic and Renewable Energy Engineering 2010 http://www.pv.unsw.edu.au/Research/3gp.asp
USDOE 2010
Bagnall, D. M.Boreland, M. 2008 “Photovoltaic technologies,”Energy Policy 36 4390CrossRefGoogle Scholar
Green, M. A. 1982 Solar Cells: Operating Principles, Technology, and System ApplicationsEnglewood Cliffs, NJPrentice-Hall, IncGoogle Scholar
Butler, D. 2008 “Thin-films: ready for their close-up?,”Nature 454 558CrossRefGoogle Scholar
ARCPCE Australian Research Council Photovoltaics Centre of Excellence 2008 ARC Photovoltaics Centre of Excellence Annual Report 2008SidneyThe University of South WalesGoogle Scholar
Fthenakis, V.Kim, H. C.Held, M.Raugei, M.Krones, J. 2009 “Update of PV energy update times and life-cycle greenhouse gas emissions,”24th European Photovoltaic Solar Energy ConferenceHamburgGoogle Scholar
Shockley, W.Queisser, H. J. 1961 “Detailed balance limit of efficiency of p–n junction solar cells,”J. Appl. Phys 32 510CrossRefGoogle Scholar
Gratzel, M. 2001 “Photoelectrochemical cells,”Nature 414 338CrossRefGoogle Scholar
Green, M. A. 2001
Andersson, B. A. 2001 Material Constraints on Technology Evolution: The Case of Scarce Metals and Emerging Energy TechnologiesGöteborgGoogle Scholar
Cranstone, D. A. 2002 A History of Mining and Mineral Exploration in Canada and Outlook for the FutureOttawaOntarioGoogle Scholar
USGS 2006 http://minerals.usgs.gov/ds/2005/140/copper.pdf
Ruth, M. 1995 “Thermodynamic constraints on optimal depletion of copper and aluminum in the United States: a dynamic model of substitution and technical change,”Ecol. Econ 15 197CrossRefGoogle Scholar
Rosa, R. N.Rosa, D. R. N. 2007 “Exergy cost of extracting mineral resources,”Proceedings of the 3rd International Energy, Exergy and Environment SymposiumMiguel, A. F.Heitor Reis, A.Rosa, R. N.Évora, PortugalCGE-Évora Geophysics CentreGoogle Scholar
Hubbert, M.K. 1956 Nuclear Energy and the Fossil FuelsHouston, TXShell Development Company, Exploration and Production Research DivisionGoogle Scholar
Gordon, R. B.Bertram, M.Graedel, T. E. 2006 “Metal stocks and sustainability,”Proc. Natl. Acad. Sci 103 1209CrossRefGoogle Scholar
Laherrere, J. 2010
Hannon, B.Ruth, M.Delucia, E. 1993 “A physical view of sustainability,”Econ 8 253Google Scholar
Hall, C. A. S.Lindenberger, D.Kummel, R.Kroeger, T.Eichhorn, W.
Ayers, R. U. 1994 Information, Entropy, and Progress: A New Evolutionary ParadigmNew YorkAmerican Institute of PhysicsGoogle Scholar
Hall, C. A. S.Cleveland, C. J.Kaufmann, R. 1986 Energy and Resource Quality: The Ecology of the Economic ProcessNew YorkJohn Wiley & Sons, Inc221Google Scholar
USGS 2010 http://minerals.usgs.gov/minerals/pubs/commodity/
ICF International 2007 Energy Trends in Selected Manufacturing Sectors: Opportunities and Challenges for Environmentally Preferable Energy OutcomesUSEPAGoogle Scholar
Fthenakis, V. M.Kim, H. C.Wang, W. 2007 Life Cycle Inventory Analysis in the Production of Metals Used in PhotovoltaicsBrookhaven National LaboratoryNew YorkCrossRefGoogle Scholar
Ullmann, F. 1985 Ullmann's Encyclopedia of Industrial ChemistryDeerfield Beach, FLVCH PublishersGoogle Scholar
George, M. 2010
Page, N. J.Creasy, S. C. 1975 “Ore grade, metal production, and energy,”J. Res. U.S. Geol. Surv 3 9Google Scholar
BCS Inc
USDOI 2000 Mining and Quarrying TrendsWashington, DCUS Geological SurveyGoogle Scholar
USDOC 1997
USDOE 2000 Estimated by Energy Efficiency and Renewable EnergyOffice of Industrial TechnologiesGoogle Scholar
Energetics Inc. and E3M Inc 2004 Energy Use, Loss and Opportunities Analysis: U.S. Manufacturing & MiningWashington, DCUS Department of Energy, Office of Energy Efficiency and Renewable Energy, Industrial Technologies ProgramGoogle Scholar
Granade, H. C. 2009 Unlocking Energy Efficiency in the U.S. EconomyMcKinsey Global Energy and Materials, McKinsey & CompanyGoogle Scholar
Marsden, J. O. 2008 “Energy efficiency and copper hydrometallurgy,”Hydrometallurgy 2008: Proceedings of the Sixth International SymposiumYoung, C. A.SMEGoogle Scholar
Castle, J. F. 1989 Energy Consumption and Costs of SmeltingLondonInstitute of Mining and MetallurgyGoogle Scholar
DOE 1980 An Assesment of Energy Requirements in Proven and New Copper ProcessesWashington, DCUS Department of EnergyGoogle Scholar
Yoshiki-Gravelsins, K. S.Toguri, J. M.Choo, R. T. C. 1993 “Metals production, energy, and the environment, part I: energy consumption,”JOM 45 15CrossRefGoogle Scholar
Gupta, A. K.Hall, C. A. S. 2011 Material Constraints and Energy Costs Associated with Rapid Upscale of PV SystemsNew YorkSUNYGoogle Scholar
Demkin, J. A.American Institute of Architects (AIA) 1996 Environmental Resource GuideNew YorkJohn WileyGoogle Scholar
University of Waterloo 2010 http://crmd.uwaterloo.ca/index.html
Kenji, T.Strongman, J. E.Maeda, S. 1986 The World Copper Industy: Its Changing Structure and Future ProspectsWashington, DCThe World BankGoogle Scholar
Porter, K. E.Peterson, G. R. 1992 “The availability of primary copper in market economy countries: a minerals availability appraisal,”Information Circular 9310 1Google Scholar
Gordon, R. B.Bertram, M.Graedel, T. E. 2007 “On the sustainability of metal supplies: a response to Tilton and Lagos,”Resources Policy 32 24CrossRefGoogle Scholar
Tilton, J. E.Lagos, G. 2007 “Assessing the long-run availability of copper,”Resources Policy 32 19CrossRefGoogle Scholar
USGS 2008 http://minerals.usgs.gov/minerals/pubs/commodity/copper/index.html#myb
Edelstein, D.Long, K. R. 2008
Gomez, F.Guzman, J. I.Tilton, J. E. 2007 “Copper recycling and scrap availability,”Resources Policy 32 183CrossRefGoogle Scholar
Matthews, V. 2007

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