Thorium Energy Alliance (TEA) is a non-governmental, non-profit 501(c)3, educational organization based in the United States, which seeks to promote energy security of the world through the use of thorium as a fuel source. The potential for the use of thorium was studied extensively during the 1950s and 60s,[1] and now worldwide interest is being revived due to limitations and issues concerning safety, economics, use and issues in the availability of other energy sources.[2][3][4][5][6][7] TEA advocates thorium based nuclear power in existing reactors and primarily in next generation reactors. TEA promotes many initiatives to educate scientists, engineers, government officials, policymakers and the general public.[8]

Thorium Energy Alliance
Formation2009 Washington, D.C., United States
TypeNon-governmental organization
PurposeEducational, Sustainable Energy
HeadquartersHarvard, Illinois
Region served
Worldwide
Executive Director
John Kutsch
Websitewww.thoriumenergyalliance.com
RemarksSee article for more details.

Energy crisis and the role of thorium

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TEA promotes the use of thorium using a different rationale. Increasing world population,[9] depleting resources[10] and global warming have put severe constraints on the choices of power generation available today.[11] Traditional fossil fuel based energy generation faces two-fold challenges in terms of depleting resources and need to keep greenhouse gas emissions in control.[12] While interim measures like natural gas and unconventional oil are proposed, these still have a carbon footprint and are not universally available.[13] Hydropower use has reached a natural limit in many parts of the world, and the existing capacity is under stress due to climate change.[14] Renewable energy is seen as an important component of future energy generation, but being essentially intermittent, can not be effectively managed by the current power distribution technologies.[15] Hence, nuclear energy is seen as an important option for power generation in many countries.[16]

Present generation nuclear reactors are all uranium based, fueled with either freshly mined uranium or recycled plutonium and uranium as the fissile material. There are concerns about a continued supply of uranium, due to resource depletion, as well as various obstacles to mining uranium deposits.[17] Moreover, the currently widely deployed nuclear reactors harness less than 3% of the energy content of uranium fuel. This technology, in turn, leaves large quantities of radioactive wastes to be disposed of safely. The issue of disposal of these wastes has not been addressed convincingly anywhere in the world. Moreover, a vast majority of the present generation reactors are based on the original design of reactors meant to power submarines, and whose safety is ensured by several active features and standard operating practices. Under various circumstances, these features and procedures were seen to fail, bringing about catastrophic consequences. Highly enriched uranium and separated plutonium are also the feedstock for nuclear weapons.

Thorium has been proposed as a clean, safe, proliferation resistant and sustainable source of energy which additionally is free from most of the issues associated with uranium.[18][19] The average crustal abundance of thorium is four times more than that of uranium. Thorium is invariably associated with rare-earth elements or rare metals like niobium, tantalum and zirconium. Hence, it can be recovered as a by-product of other mining activities. Already, large quantities of thorium recovered from rare-earth element operations have been stockpiled in many countries. Thorium is fertile material, and essentially all thorium can be used in a nuclear reactor. Thorium is not fissile in itself, absorbs a neutron to transmute into uranium-233, which can fission to produce energy. Therefore, a thorium based fuel cycle produces very little, easily manageable waste compared to uranium.[20] Thorium based fuel cycle options can be used to 'burn' all the presently accumulated nuclear waste. Various thorium based reactor designs are inherently more safe than uranium based reactors.[21] However nuclear proliferation using thorium has proven to be extremely difficult and non-practical, although proof-of-concepts of the contrary also have been proposed.[22]

Despite all the favorable factors, and use in commercial reactors in the past,[23][24] interest in thorium diminished in the late 1980s due to various reasons. Critics of thorium claim that the advantages are overstated and it is unlikely to be a useful source of energy. Experts point the adverse economics and the availability of plentiful sources of energy that will deter full commercialization of thorium based energy. These and other issues regarding the use of thorium have been debated.[25][26][27][28]

Advocacy for thorium

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One of the stated objectives of TEA is the vigorous advocacy for use of thorium as a nuclear fuel. TEA through its activities reaches out to scientists, engineers, government official, policymakers, and lawmakers to sensitize about the advantages of using thorium as a fuel. TEA has conducted a number of publicity campaigns and social media based outreach activities. TEA has emphasized the research and development done in the USA during the 1950s to 1970s period on thorium based reactor designs and fuel cycle options. Of particular interest was the Molten-Salt Reactor Experiment (MSRE) carried out at Oak Ridge National Laboratory, the United States during 1964–1969.[29][30]

TEA argues the importance of enabling thorium energy, especially in liquid fluoride thorium reactor (LFTR pronounced lifter), in public hearings, such as the Blue Ribbon Commission on America's Nuclear Future.[31] TEA promotes the establishment of a working thorium powered reactor. TEA is particularly interested in restarting the homogeneous fuels research program and the commercialization of molten salt reactor[32] and the supply chain infrastructure to support it.[33]

Another aim of TEA is supporting the reemergence of a Western Rare Earths Infrastructure by bringing together rare-earth producers leading to the establishment of a consortium for refining rare earths and sequestering thorium for future use.[34] TEA supports changes in existing thorium regulation in the US to promote safe production and stockpiling of thorium as a by-product of associated mineral industries activity.

Activities

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TEA proposes to leverage education and training activities by:

  • creating educational resources and textbooks
  • providing scholarships
  • facilitation of expert speakers
  • producing museum exhibits presenting thorium based energy

TEA plans to engage politicians through round-table discussions and provide them with expert opinion, white papers, executive summaries and talking points to demonstrate thorium technology.[35]

There is a major initiative to engage the public through regular and social media channels. TEA facilitates experts to appear on radio and television and participate in group discussions and provide interviews. In this direction TEA generates a large quantity of its own media including, webcasts, podcasts, videos, pamphlets,[36] books and articles. TEA sponsors advertising campaigns in print, television and targeted mail.

Thorium Energy Alliance has supported a dozen research projects at the Nanotechnology Lab at University of Missouri St Louis (UMSL), which is located in an Economic Opportunity Zone.

Thorium Energy Alliance has supported Outreach to youth through stem-based organizations such as Generation Atomic, North American Young Generation in Nuclear, and Mothers for Nuclear, encouraging young people to get involved in the industry.

The Thorium Energy Alliance website has added resources for international organizations and National Labs in the USA as well as industry and Military.The website acts as a resource and an encyclopedia for the history and applications of thorium as well as or repository of all of conference information and related papers and topical documents.

Thorium Energy Alliance has offered Techno-Economic support for the development of nuclear medicines, such as Bismuth and Actinium, derived from Thorium extraction processes.

Thorium Energy Alliance has worked with Rare Earth organizations and the critical minerals institute (CMI) to solve the critical materials issues in the United States and the Western world by providing thorium policy guidance with the goal to allow a new domestic Rare Earth Metals industry to start.

The Government of El Salvador and Thorium Energy Alliance have signed a Memorandum of Understanding to promote the "El Salvador Energy Bridge" plan for clean energy through thorium.[37] The document was signed by Daniel Alvarez, Director General of Energy, Hydrocarbons and Mines (DGEHM), and John Kutsch, Executive Director of Thorium Energy Alliance, at the Embassy of El Salvador in Washington D.C., with Ambassador Milena Mayorga as a witness of honor.

In the future, TEA plans to track the milestones in the creation of a thorium economy. One of the proposed methods will be to create a thorium and related technology stock portfolio and a Thorium ETF, which will allow the public to track and participate in the growing value of the thorium economy.[38]

Annual conferences

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TEA organizes regular annual conferences since 2009, where scientific sessions and cross-cutting energy and fuel management discussions bring together a cross-section of interested domain experts.[39] The inaugural conference in 2009 took place in Washington, D.C., followed by California (2010), Washington, D.C. (2011), and Chicago (2012). The 2013 annual conference was held in Chicago, May 30–31.

The tenth conference, TEAC10, was held at the Pollard Technology Conference Center in Oak Ridge, Tennessee, on October 1, 2019.

The eleventh conference, TEAC11, will be held on October 13–15 2022 in Albuquerque, New Mexico, at the national nuclear energy Museum in Albuquerque. TEA has sponsored the production of a new exhibit on thorium energy and advanced reactors.  The conference is being put on with participation of the University of New Mexico, Abilene Christian University Nuclear Department, the nuclear museum, and the support of several of the startups that TEA has assisted with technological support and policy information.

See also

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References

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  1. ^ Seaborg, Glenn T. (1962), Civilian nuclear power: A report to the President (PDF), Washington, D.C.: U.S. Atomic Energy Commission, p. 67, archived from the original (PDF) on March 30, 2014, retrieved January 9, 2013
  2. ^ Farrimond, Stuart (March 24, 2011). "The Future of Nuclear Power after Fukushima: Thorium Reactors?". Doctor Stu's Blog. Archived from the original on July 8, 2013. Retrieved January 9, 2013.{{cite web}}: CS1 maint: unfit URL (link)
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  8. ^ Curwin, Trevor (December 21, 2010). "New Power Source For Nuclear Plants in the Wings". CNBC. Retrieved January 9, 2013.
  9. ^ "Booming nations 'threaten Earth'". BBC. January 12, 2006. Retrieved January 9, 2013.
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  11. ^ Biello, David (October 27, 2011). "Another Inconvenient Truth: The World's Growing Population Poses a Malthusian Dilemma". Scientific American. Retrieved January 9, 2013.
  12. ^ Porter, Adam (June 10, 2005). "'Peak oil' enters mainstream debate". BBC. Retrieved January 9, 2013.
  13. ^ Bilek, Marcela; Hardy, Clarence; Lenzen, Manfred; Dey, Christopher (2008). "Life-cycle energy balance and greenhouse gas emissions of nuclear energy: A review" (PDF). Energy Conversion & Management. 49 (8): 2178–2199. doi:10.1016/j.enconman.2008.01.033. Retrieved January 9, 2013. SLS – USydUSyd-ISApubspandora-archive
  14. ^ Urban, Frauke and Mitchell, Tom (2011). Climate change, disasters and electricity generation Archived January 9, 2012, at the Wayback Machine. London: Overseas Development Institute and Institute of Development Studies
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  20. ^ Thompson, John (February 22, 2010). "Could the Clean Energy We Need Be Right Under Our Feet?". GQ Magazine. Retrieved January 9, 2013.
  21. ^ Shiga, David (March 23, 2011). "Thorium reactors could rescue nuclear power". New Scientist (2805): 8–10.
  22. ^ Ashley Stephen F.; Parks; Geoffrey T.; Nuttall; William J.; Boxall; Colin & Grimes; Robin W. (December 6, 2012). "Nuclear energy: Thorium fuel has risks". Nature. 492 (7427): 31–33. Bibcode:2012Natur.492...31A. doi:10.1038/492031a. PMID 23222590. S2CID 4414368.
  23. ^ Adams, Rod (October 1, 1995). "Light Water Breeder Reactor: Adapting A Proven System". Atomic Insights. Archived from the original on October 28, 2012. Retrieved January 17, 2013.
  24. ^ World Nuclear Association (October 1, 1995). "Thorium". Archived from the original on February 16, 2013. Retrieved January 17, 2013.
  25. ^ Edwards, Gordon (July 13, 2011). "Thorium Reactors: Back to the Dream Factory". Canadian Coalition for Nuclear Responsibility. Retrieved January 11, 2013.
  26. ^ Makhijani, Arjun; Boyd, Michele (2009). "Thorium Fuel: No Panacea for Nuclear Power" (PDF). Institute for Energy and Environmental Research and Physicians for Social Responsibility. Retrieved February 3, 2013.
  27. ^ Cannara, Alexander (May 12, 2010). "IEER/PSR Thorium "Fact Sheet" Rebuttal". Energy from Thorium. Retrieved February 3, 2013.
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  30. ^ LeBlanc, David (May 2010). "Too Good to Leave on the Shelf". Mechanical Engineering. 132 (5): 29–33. doi:10.1115/1.2010-May-2. Retrieved January 9, 2013.
  31. ^ Kutsch, John (September 8, 2010). TEA Resources. Washington, D.C.: Thorium Energy Alliance.
  32. ^ Niiler, Eric (February 29, 2012). "Nuclear power entrepreneurs push thorium as a fuel". The Washington Post. Archived from the original on October 1, 2013. Retrieved January 17, 2013.
  33. ^ Martin, Richard (December 21, 2009). "Uranium Is So Last Century – Enter Thorium, the New Green Nuke". Wired. Vol. 18, no. 1. Retrieved January 9, 2013.
  34. ^ Bond, Christopher S. (2010), Brazil and U.S. Initiative on Rare Earths (PDF), Washington D.C., archived from the original (PDF) on November 4, 2011, retrieved January 9, 2013{{citation}}: CS1 maint: location missing publisher (link)
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  37. ^ El Salvador picks thorium for part of its energy future, ANS
  38. ^ Objectives, Needs, and Next Steps for a Thorium Alliance, Thorium Energy Alliance
  39. ^ Jacoby, Mitch (November 16, 2009). "Reintroducing Thorium". Chemical & Engineering News. ISSN 0009-2347. Retrieved January 9, 2013.

Further reading

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