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Mineral Economics

, Volume 31, Issue 1–2, pp 221–227 | Cite as

Revisiting the long-run energy mix with the global energy market model (GEM)

  • Roberto F. Aguilera
  • Roberto Aguilera
Original Paper

Abstract

The objective of this paper is to estimate the long-run energy mix—i.e., the combination of resources including solids, liquids, and gases that will satisfy energy demand to the year 2040—with a Global Energy Market model (GEM). The GEM first provides a close match of the historical energy mix dating back to 1850 and is then used to make forecasts for the future. Originally developed in 2007, the model was used at that time to project the energy mix to the year 2030. The original findings from 2007 introduced a “2030 1/3 forecast,” indicating that solids, liquids, and gases would each occupy a third of the energy market in 2030. After further disaggregating the categories, it was found that liquids, mostly oil, would experience a declining market share by 2030 while natural gas would see a rapid rise. The solids’ share, mostly coal, was relatively flat by that time. This paper uses the most recent statistics of the last 10 years on consumption of different energy sources to verify the accuracy of the original GEM baseline scenario carried out in 2007. Once the results are proven reasonable, the scenario’s time horizon is extended to the year 2040—a limit in which outcomes can be reasonably conceptualized and quantified. Our findings show continued penetration of natural gas in the energy mix—a result consistent with efforts to reduce carbon emissions. In reality, that outcome will be contingent on the enactment of policies that encourage the development, transportation, and consumption of gas.

Notes

References

  1. Aguilera RF (2006) Assessing the long run availability of global fossil energy resources. PhD Dissertation, Colorado School of MinesGoogle Scholar
  2. Aguilera RF and Aguilera R (2007) Assessing the past, present, and near future of the global energy market. SPE paper 110215-PP presented at the annual technical conference and exhibition held in Anaheim, California, USA, November 11-14.  https://doi.org/10.2118/110215-MS
  3. Aguilera RF and Aguilera R (2008) Assessing the past, present, and near future of the global energy market. J Petrol Technol 36–39. Google Scholar
  4. Aguilera RF, Aguilera R (2012) World natural gas endowment as a bridge towards zero carbon emissions. Technol Forecast Soc Change 79:579–586CrossRefGoogle Scholar
  5. Aguilera RF, Radetzki M (2014) The shale revolution: global gas and oil markets under transformation. Miner Econ 26:75–84CrossRefGoogle Scholar
  6. Aguilera RF, Radetzki M (2015) The price of oil. Cambridge University Press, CambridgeGoogle Scholar
  7. BP, annual, Statistical Review of World Energy. British Petroleum, United KingdomGoogle Scholar
  8. Fisher JC and Pry RH (1970) A simple solution model of technological change. Report 70_C-215, General Electric Company, Research and Development Center, New YorkGoogle Scholar
  9. Grubler A (2004) Transitions in energy use. Encycl Energy 6:163–177Google Scholar
  10. Hefner III RA (2002) The age of energy gases in the new millennium, the GHK company, Oklahoma City, OK (2002). Based on presentations at 10th Repsol-Harvard Seminar on Energy Policy in Madrid, Spain, June 1999, and the SPE Gas Technology Symposium in Calgary, Canada, April 30Google Scholar
  11. Hefner RA III (2009) The grand energy transition: the rise of energy gases, sustainable life and growth, and the next great economic expansion. John Wiley & Sons, New JerseyGoogle Scholar
  12. International Energy Agency (2016) World energy outlook. Paris, FranceGoogle Scholar
  13. Marchetti C and Nakicenovic N (1979) The dynamics of energy systems and the logistic substitution model. Report RR-79-13, International Institute for Applied Systems Analysis (IIASA) Publications, LaxenburgGoogle Scholar
  14. Marchetti C (1985) Nuclear plants and nuclear niches. Nucl Sci Eng 90:521–526CrossRefGoogle Scholar
  15. Organization of the Petroleum Exporting Countries (2016) World Oil Outlook. Vienna, AustriaGoogle Scholar
  16. Radetzki M, Wårell L (2017) A handbook of primary Commodities in the Global Economy, 2nd edn. Cambridge University Press, CambridgeCrossRefGoogle Scholar
  17. Söderholm P (2001) Fuel for thought: European energy market restructuring and the future of power generation gas use. Int J Global Energy Issues 16(4):313–327CrossRefGoogle Scholar

Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2017

Authors and Affiliations

  1. 1.Curtin Business SchoolCurtin UniversityPerthAustralia
  2. 2.Schulich School of EngineeringUniversity of CalgaryCalgaryCanada

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