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Lithium - the Metal of the Future?

Published online by Cambridge University Press:  25 January 2013

Ihor A. Kunasz
Ihor A. Kunasz*
Affiliation:
TRU Group, 95 Prince Arthur Avenue, Suite 117, Toronto, ON, Canada
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Abstract

The second half of the twentieth century saw a dramatic shift in lithium chemicals production from traditional pegmatite sources to brines. Today, the bulk of lithium carbonate, which serves as the raw material for various downstream lithium chemicals, including lithium metal for the lithium batteries, is produced from the brines of the Salar de Atacama, Chile, the Salar del Hombre Muerto, Argentina and Clayton Valley Nevada, U.S.A. There is minor production in Tibet and the People’s Republic of China (PRC). Australian spodumene concentrates are converted to lithium carbonate in the PRC.

The resurgence in the potential development of electric cars has resulted in the increased exploration for and identification of potential new lithium brine operations and the reassessment of some pegmatite deposits.

A number of predictions for a potentially large electric car market scenario have raised questions on the availability of sufficient lithium resources. However, since the original 1976 report on global lithium resources by the National Academies of Sciences and Engineering, newly identified deposits have almost quadrupled the total potentially available lithium resources. Based on the best predictions, the lithium supply is more than adequate to meet the demand for electric cars well into the 21st century.

Keywords

Lichemical compositioneconomics
Type
Articles
Information
MRS Online Proceedings Library (OPL) , Volume 1492: Symposium D/G – Materials for Sustainable Development—Challenges and Opportunities , 2013 , pp. 3 - 14
Copyright
Copyright © Materials Research Society 2013 

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References

REFERENCES:

O’Neill, B. J., Kunasz, I.A., Wright, L.A., 1969, “The Lithium Production Curve: A Measure of Many Things”, Earth and Mineral Sciences, Vol. 38, No. 6, The Pennsylvania State University, University Park, PA.Google Scholar
Talison Lithium Limited, 2011, N43–101 Technical Report;Google Scholar
Galaxy Resources Ltd., 2012, Ni43–101, Quarterly Report Google Scholar
Barrett, W.T., and O’Neill, B.J. Jr., 1970, “Recovery of Lithium from Saline Brines Using Solar Evaporation,” 3rd Salt Symposium, Rau, J.L. and Dellwig, L.F., eds., Vol. 2, Northern Ohio Geological Society, Inc., Cleveland, pp. 4750.Google Scholar
Moraga, B.A., et al. , 1974, “Estudio Geologico del Salar de Atacama, Provincia de AntofagastaInstituto de Investigaciones Geologicas de Chile, Bulletin 29, 56 pp.Google Scholar
Nicolli, H.B., et al. ., 1980, “Caracteristicas Geoquimicas de Aguas y Salmueras de la Puna Argentina,” Miscelana No. 63, Academia Nacional de Ciencas, Cordoba, Argentina, pp. 338.Google Scholar
Ballivian, O., and Risacher, F., 1981, “Les Bassins a Evaporites de l’Altiplano Bolivien, ORSTOM, Paris, pp. 109–135.Google Scholar
http://www.westernlithium.com Google Scholar
http://www.simbolmaterials.com Google Scholar
http://www.albemarle.com Google Scholar
http://www.riotintominerals.com/./RTM.JadarFactSheets.Sept2011.pdf Google Scholar
http://www.sqm.com - “U.S. Securities Exchange Commission Form 20F, 2011” Google Scholar
http://www.rockwoodspecialties.com Google Scholar
http://www.fmclithium.com Google Scholar
Kesler, T., 1978, Raw Lithium Supplies, Mining Engineering, Vol. XXX.Google Scholar
Evans, R.K., 2012, An Overabundance of Lithium? Industrial Minerals, Lithium Supply and Market Conference, Buenos Aires, Argentina Google Scholar
Kunasz, I. A., 2006, Lithium Resources, Industrial Minerals and Rocks: Commodities, Markets and Uses, Society for Mining, Metallurgy, and Exploration, pp. 601–613 Google Scholar
Clarke, G., 2012, “Advancing lithium projects & expansions”, Industrial Minerals, London.Google Scholar
http://venturebeat.com/2011/04/27/jd-power-electric-caroverhype/# m6eFU0exs5MBSMH2.99Google Scholar
Anderson, E R., 3rd Lithium Supply & Markets, 2011, “Shocking Future Battering the Lithium Industry through 2020”, 3rd Lithium Supply & Market Conference, Toronto, Canada Google Scholar
Anderson, E.R., 2012, “TRU Long-range supply-demand forecast for global lithium 2020”. TRU Group, Toronto, Canada.Google Scholar
www.reuters.com, Sept 24 2012, “Toyota drops plan for widespread sales of electric car” Google Scholar
Petersen, J., 2012, “Electric Vehicle Battery Grants, 3 Years Of Disappointment And Failure” in http://www.seekingalpha.com.Google Scholar