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ITER

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ITER is an international tokamak (magnetic confinement fusion) research project designed to demonstrate the scientific and technological feasibility of a full-scale fusion power reactor. ITER is intended to be an experimental step between today's studies of plasma physics and future electricity-producing fusion power plants. It builds upon research conducted on devices such as DIII-D, EAST, TFTR, JET, JT-60, and T-15, and will be considerably larger than any of them.

On November 21, 2006, the seven participants formally agreed to fund the project.[1] The program is anticipated to last for 30 years — 10 years for construction, and 20 years of operation — and cost approximately 10 billion (US$12.1 billion), making it the third most expensive scientific project after the Manhattan Project and the International Space Station. It will be based in Cadarache, France. It is technically ready to start construction and the first plasma operation is expected in 2016.

ITER is designed to produce approximately 500 MW (500,000,000 watts) of fusion power sustained for up to 500 seconds (compared to JET's peak of 16 MW for less than a second). A future fusion power plant would generate about 3000-4000 MW of thermal power. Although ITER will produce net power in the form of heat, the generated heat will not be used to generate any electricity.

According to the ITER consortium, fusion power offers the potential of "environmentally benign, widely applicable and essentially inexhaustible"[2][3] electricity, properties that they believe will be needed as world energy demands increase while simultaneously greenhouse gas emissions must be reduced,[4] justifying the expensive research project.

ITER was originally an acronym standing for International Thermonuclear Experimental Reactor; that title was dropped to avoid the negative popular connotations of 'thermonuclear' and 'experimental'. 'Iter' also means 'the journey' or 'the path' in Latin, and this double meaning reflects ITER's role in harnessing nuclear fusion as a peaceful power source.

Objectives

The official objective of ITER is to "demonstrate the scientific and technological feasibility of fusion energy for peaceful purposes". ITER has a number of specific objectives, all concerned with developing a viable fusion power reactor:

  • To momentarily produce ten times more thermal energy from fusion heating than is supplied by auxiliary heating (a Q value of 10).
  • To produce a steady-state plasma with a Q value of greater than 5.
  • To maintain a fusion pulse for up to eight minutes.
  • To ignite a 'burning' (self-sustaining) plasma.
  • To develop technologies and processes needed for a fusion power plant — including superconducting magnets and remote handling (maintenance by robot).
  • To verify tritium breeding concepts.

Reactor overview

File:Tokmak - ITER cut.jpg
Technical Cutaway of the ITER Tokamak Torus encasing.
See also: nuclear fusion

When deuterium and tritium fuse, two nuclei come together to form a helium nucleus (an alpha particle), and a high energy neutron.

While in fact nearly all stable isotopes lighter on the periodic table than iron will fuse with some other isotope and release energy, deuterium and tritium are by far the most attractive for energy generation as they require the lowest temperatures to do so en masse.

All proto- and mid-life stars radiate enormous amounts of energy generated by fusion processes. Mass for mass, the deuterium-tritium fusion process releases roughly three times as much energy as uranium 235 fission, and millions of times more energy than a chemical reaction such as the burning of coal. It is the goal of a fusion power plant to harness this energy to produce electricity.

The activation energy for fusion is so high because the protons in each nucleus will tend to strongly repel one another, as they each have the same positive charge. A heuristic for estimating reaction rates is that nuclei must be able to get within 1 femtometer (1 × 10−15 meter) of each other, where the nuclei are increasingly likely to undergo quantum tunnelling past the electrostatic barrier and the turning point where the strong nuclear force and the electrostatic force are equally balanced, allowing them to fuse. In ITER, this distance of approach is made possible by high temperatures and magnetic confinement. High temperatures give the nuclei enough energy to overcome their electrostatic repulsion (see Maxwell-Boltzmann distribution). For deuterium and tritium, the optimal reaction rates occur at temperatures on the order of 100,000,000 K. The plasma is heated to a high temperature by ohmic heating (running a current through the plasma). Additional heating is applied using neutral beam injection (which cross magnetic field lines without a net deflection and will not cause a large electromagnetic disruption) and radio frequency (RF) or microwave heating.

At such high temperatures, particles have a vast kinetic energy, and hence velocity. If unconfined, the particles will rapidly escape, taking the energy with them, cooling the plasma to the point where net energy is no longer produced. A successful reactor would need to contain the particles in a small enough volume for a long enough time for much of the plasma to fuse. In ITER and many other magnetic confinement reactors, the plasma, a gas of charged particles, is confined using magnetic fields. A charged particle, when crossing a magnetic field, does not escape if left unperturbed. It simply spins around the magnetic field, in Larmor gyrorotation. The particle may move along the magnetic field unopposed by the field, but if the field is wrapped into a toroidal or doughnut shape, it is then confined.

A solid confinement vessel is also needed, both to shield the magnets and other equipment from high temperatures and energetic photons and particles, and to maintain a near-vacuum for the plasma to populate. The containment vessel is subjected to a barrage of very energetic particles, where electrons, ions, photons, alpha particles, and neutrons constantly bombard the surface and degrade the structure. The material must be designed to stand-up to this environment for long enough so that an entire powerplant would be economical. Tests of such materials will be carried out both at ITER and at IFMIF(International Fusion Materials Irradiation Facility).

Once fusion has begun, high energy neutrons will radiate from the reactive regions of the plasma, crossing magnetic field lines easily due to charge neutrality (see neutron flux). Since it is the neutrons that receive the majority of the energy, they will be ITER's primary source of energy output. Ideally, alpha particles will expend their energy in the plasma, further heating it.

Beyond the inner wall of the containment vessel one of several test blanket modules is to be placed. These modules are designed to slow and absorb neutrons in a reliable and efficient manner, limiting damage to the rest of the structure, and breeding tritium from lithium and the incoming neutrons for fuel. Energy absorbed from the fast neutrons is extracted and passed onto the primary coolant. This heat energy would then be used to power an electricity-generating turbine in a real power plant; however, in ITER this heat is not of scientific interest, and will simply be released.

History

ITER began in 1985 as a collaboration between the European Union (through EURATOM), the USA, then the Soviet Union and Japan. Conceptual and engineering design phases led to an acceptable, detailed design in 2001, underpinned by US$650 million worth of research and development by the "ITER Parties" to establish its practical feasibility. These parties (with the Russian Federation replacing the Soviet Union and with the USA opting out of the project in 1999 and returning in 2003) were joined in negotiations on the future construction, operation and decommissioning of ITER by Canada (who then terminated their participation at the end of 2003), the People's Republic of China, and the Republic of Korea. India officially became part of ITER on 6 December 2005. The project is expected to cost about €10 billion (US$13 billion) over its thirty year life.

File:ITER reactor cutout.png
The ITER design, as of 1993

On 28 June 2005, it was officially announced that ITER will be built in the European Union in Southern France. The negotiations that led to the decision ended in a compromise between the EU and Japan, in that Japan was promised 20 percent of the research staff on the French location of ITER, as well as the head of the administrative body of ITER. In addition, another research facility for the project will be built in Japan, and the European Union has agreed to contribute about 50% of the costs of this institution.[5]

On November 21 2006, an international consortium signed a formal agreement to build the reactor.[6]

ITER will run in parallel with a materials test facility, the International Fusion Materials Irradiation Facility (IFMIF), which will develop materials suitable for use in the extreme conditions that will be found in future fusion power plants. Both of these will be followed by a demonstration power plant, DEMO, which would generate electricity. DEMO would be the first to produce electric energy for commercial use.

A "fast track" road-map to a commercial fusion power plant has been sketched out.[7] This scenario, which assumes that ITER continues to demonstrate that the tokamak line of magnetic confinement is the most promising for power generation, anticipates a full-scale power plant coming on-line in 2050, potentially leading to a large-scale adoption of fusion power over the following thirty years.

Location

Location of Cadarache, France, EU

The process of selecting a location for ITER was long and drawn out. The most likely sites were Cadarache in Provence-Alpes-Côte-d'Azur, France and Rokkasho, Aomori, Japan. Additionally, Canada announced a bid for the site in Clarington in May 2001, but withdrew from the race in 2003. Spain also offered a site at Vandellos on 17 April 2002, but the EU decided to concentrate its support solely behind the French site in late November 2003. From this point on the choice was between France and Japan.

On 3 May 2005, the EU and Japan agreed to a process which would settle their dispute by July.

At the final meeting in Moscow on 28 June 2005, the participating parties agreed on the site in Cadarache in Provence-Alpes-Côte-d'Azur, France.

Construction of the ITER complex is planned to begin in 2008, while assembly of the tokamak itself is scheduled to begin in the year 2011. Unforeseen political, financial, or even social issues could alter these estimated dates substantially.[8]

Participants

Currently there are seven national and supranational parties participating in the ITER program: China, the European Union, India, Japan, Russia, South Korea, and the USA.[9]

Three of them (Russia, Europe and Japan) already have made such experimental devices. Most recently, China announced in 2006 the development of an "Artificial Sun." [10]

Funding

As it stands now, the proposed costs are €10 billion for the construction of ITER, its maintenance and the research connected with it during its lifetime. At the June 2005 conference in Moscow the participating members of the ITER cooperation agreed on the following division of funding contributions: 50% by the hosting member, the European Union and 10% by each non-hosting member.[11] According to sources at the ITER meeting at Jeju, Korea, the six non-host partners will now contribute 6/11th of the total cost — a little over half — while the EU will put in the rest. As for the industrial contribution, five countries (China, India, Korea, Russia, and the US) will contribute 1/11th each for 5/11th total, Japan 2/11th, and EU 4/11th.[12]

Note that although Japan's financial contribution as a non-hosting member is 1/11th of the total, the EU agreed to grant it a special status so that Japan will provide for 2/11th of the research staff at Cadarache and be awarded 2/11th of the construction contracts, while the European Union's staff and construction components contributions will be cut from 5/11th to 4/11th.

Criticism

Bridget Woodman of Greenpeace said "Pursuing nuclear fusion and the ITER project is madness. Nuclear fusion has all the problems of nuclear power, including producing nuclear waste and the risks of a nuclear accident."[13] "Governments should not waste our money on a dangerous toy which will never deliver any useful energy," said Jan Vande Putte of Greenpeace International. "Instead, they should invest in renewable energy which is abundantly available, not in 2080 but today."[14]

French environmental groups said the project ITER, was "dangerous", "costly", and "not a job generator". A French association including about 700 anti-nuclear groups, Sortir du nucléaire (Get Out of Nuclear Energy), also claimed that ITER was a hazard because scientists did not yet know how to manipulate the high-energy deuterium and tritium hydrogen isotopes used in the fusion process.[15]

The ITER project confronts numerous technically challenging issues. Pierre-Gilles de Gennes, French Nobel laureate in Physics (though not a fusion specialist) is well known for saying: "We say that we will put the sun into a box. The idea is pretty. The problem is, we don't know how to make the box."

A technical concern is that the 14 MeV neutrons produced by the fusion reactions will damage the materials from which the reactor is built.[16] Research is in progress at IFMIF to determine how and/or if reactor walls can be designed to last long enough to make a commercial power plant economically viable in the presence of the intense neutron bombardment. The damage is primarily caused by high energy neutrons knocking atoms out of their normal position in the crystal lattice. A related problem for a future commercial fusion power plant is that the neutron bombardment will induce radioactivity in the loreactor itself. Maintaining and decommissioning a commercial reactor may thus be difficult and expensive.

Rebecca Harms, Green/EFA member of the European Parliament's Committee on Industry, Research and Energy, said: "In the next 50 years nuclear fusion will neither tackle climate change nor guarantee the security of our energy supply." Arguing that the EU's energy research should be focused elsewhere, she said: "The Green/EFA group demands that these funds be spent instead on energy research that is relevant to the future. A major focus should now be put on renewable sources of energy." French Green party lawmaker Noël Mamère claims that more concrete efforts to fight present-day global warming will be neglected as a result of ITER: "This is not good news for the fight against the greenhouse effect because we're going to put ten billion euros towards a project that has a term of 30-50 years when we're not even sure it will be effective."[17]

A number of fusion researchers working on non-tokamak systems, such as Robert Bussard and Eric Lerner, have been critical of ITER for diverting funding that they believe could be used for more reasonable and/or cost effective fusion power plant designs. Criticisms levied often revolve around an unwillingness by ITER supporters to face up up to potential problems (both technical and economic) due to the number of scientists' jobs that are on the line with tokamak research.

Response to criticism

Proponents believe that much of the ITER criticism is misleading and inaccurate, in particular the allegations of the experiment's "inherent danger". The stated goals for a commercial fusion power station design are that the amount of radioactive waste produced be hundreds of times less than that of a fission reactor, that it produces no long-lived radioactive waste, and that it is impossible for any fusion reactor to undergo a large-scale runaway chain reaction. This is because direct contact with the walls of the reactor would contaminate the plasma, cooling it down immediately and stopping the fusion process. Besides the amount of fuel planned to be contained in a fusion reactor chamber (one half gram of deuterium/tritium fuel[18]) is only enough to sustain the reaction for an hour at maximum,[19] whereas a fission reactor usually contains several years' worth of fuel.[20] Proponents note that large-scale fusion power — if it works — will be able to produce reliable electricity on demand and with virtually zero pollution (no gaseous CO2 / SO2 / NOx by-products are produced).

According to researchers at a demonstration reactor in Japan, a fusion generator should be feasible in the 2030s and no later than the 2050s. Japan is pursuing its own research program with several operational facilities exploring different aspects of practicability.[21]

The cost of any scientific or engineering project must be weighed carefully against its possible benefit. In the United States alone, electricity accounts for US$210 billion in annual sales.[22] Asia's electricity sector attracted US$93 billion in private investment between 1990 and 1999.[23] These figures take into account only current prices. With petroleum prices widely expected to rise, political pressure on carbon production, and steadily increasing demand, these figures will necessarily also rise. Proponents contend that an investment in research now should be viewed as an attempt to earn a far greater future return for the economy. Also, worldwide investment of less than US$1 billion per year into ITER is not incompatible with concurrent research into other methods of power generation.

Contrary to criticism, proponents of ITER assert that there are significant employment benefits associated with the project. ITER will provide employment for hundreds of physicists, engineers, material scientists, construction workers and technicians in the short term, and if successful, will lead to a global industry of fusion-based power generation. Given the potential environmental, economic, and scientific benefits of harnessing fusion and its associated technologies, the pursuit of local employment opportunities could be viewed as short-sighted.

Supporters of ITER emphasize that the only way to convincingly prove ideas for withstanding the intense neutron flux is to experimentally subject materials to that flux — one of the primary missions of ITER and the IFMIF,[24] and both facilities will be of vital importance to the effort due to the differences in neutron power spectra between a real D-T burning plasma and the spectrum to be produced by IFMIF.[25] The purpose of ITER is to explore the scientific and engineering questions surrounding fusion power plants, such that it may be possible to build one intelligently in the future. It is nearly impossible to get satisfactory theoretical results regarding the properties of materials under an intense energetic neutron flux, and burning plasmas are expected to have quite different properties from externally heated plasmas.[citation needed] The point has been reached, according to supporters, where answering these questions about fusion reactors by experiment (via ITER) is an economical research investment, given the monumental potential benefit.

Finally, supporters point out that other potential replacements to the current use of fossil fuel sources have environmental issues of their own. Solar, wind, and hydroelectric power all have a relatively low power output per square kilometer compared to ITER's successor DEMO which, at 5000MW, should have an energy density that exceeds even large fission power plants[26] If fusion ever becomes commercially viable, greenhouse gas emissions from electric power generation could be almost completely eliminated, with minimal environmental impact and without long-term nuclear waste issues.

References

  1. ^ http://www.newscientisttech.com/article/dn10633-green-light-for-nuclear-fusion-project.html
  2. ^ http://www.iter.org/Benefits.htm Advantages of fusion energy
  3. ^ http://newenergytimes.com/PR/FusionAdvantages.htm
  4. ^ http://www.iter.org/fr3.htm Energy Demand
  5. ^ http://www.asahi.com/english/Herald-asahi/TKY200506280351.html
  6. ^ http://news.bbc.co.uk/1/hi/sci/tech/6165932.stm
  7. ^ http://www.iter.org/Future-beyond.htm
  8. ^ http://www.iter.org/pics/constructionschedule.pdf
  9. ^ http://www.spacewar.com/news/nuclear-civil-05zzzx.html Members of the ITER
  10. ^ http://www.angolapress-angop.ao/noticia-e.asp?ID=409853 announcement of "Artificial Sun" development in China
  11. ^ http://www.itercad.org/pr_ministers_jun05.html
  12. ^ http://www.flonnet.com/fl2301/stories/20060127003709900.htm A nuclear leap, Frontline, Vol 23, Iss 1, (Jan. 14 - 27, 2006)
  13. ^ http://www.eubusiness.com/press/EUPress.2003-11-26.3159
  14. ^ http://www.greenpeace.org/international/press/releases/ITERprojectFrance
  15. ^ http://www.dw-world.de/dw/article/0,1564,1631650,00.html
  16. ^ http://ieeexplore.ieee.org/iel5/6866/18462/00849850.pdf
  17. ^ http://www.euractiv.com/Article?tcmuri=tcm:29-141693-16&type=News
  18. ^ http://www.iter.org/safety_process.htm
  19. ^ http://www.state.gov/g/oes/rls/fs/2003/26004.htm
  20. ^ http://www.stpnoc.com/FYI.htm 1/3 of fuel rods changed ever 18 months
  21. ^ http://www.iop.org/EJ/abstract/0029-5515/45/2/004 Nucl. Fusion 45 (2005) 96–109 "Demonstration tokamak fusion power plant for early realization of net electric power generation"
  22. ^ http://www.eia.doe.gov/cneaf/electricity/chg_str_fuel/html/frontintr.html
  23. ^ http://www.findarticles.com/p/articles/mi_qa3650/is_200207/ai_n9093799
  24. ^ http://www.iter.org/operation.htm
  25. ^ http://www.nndc.bnl.gov/proceedings/2004csewgusndp/tuesday/mbphysics/09_DSmith.pdf
  26. ^ http://www.eia.doe.gov/cneaf/nuclear/page/at_a_glance/states/statesaz.html
  • ITER home page, includes pictures and diagrams available to use for educational purposes