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Page added on May 12, 2018

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Charting the International Roadmap to a Demonstration Fusion Power Plant

Charting the International Roadmap to a Demonstration Fusion Power Plant thumbnail

More than 60 top fusion scientists and engineers from around the world gathered at the 5th IAEA DEMO Programme Workshop in Daejeon, South Korea, from 7 to 10 May, to discuss critical issues and next steps on the road to the realization of fusion energy.

While science and technology issues for fusion power are broadly agreed upon, upscaling the technology to commercial electricity generation is still decades away. This workshop aimed to help experts define the facilities and activities that can lead to the resolution of some of the key scientific and technological challenges to developing a fusion demonstration power plant (DEMO).

Such DEMO would show that controlled nuclear fusion can generate net electrical power and mark the final step before the construction of a commercial fusion power plant. This would represent the next stage after ITER, the world’s largest fusion experiment under way, which is expected to demonstrate by the late 2030s that fusion can be used to generate net energy, i.e. produce more energy than supplied to it to feed the reactor. Crucially, however, energy produced by ITER will not be transmitted to the electricity grid.

Dealing with the heat

Fusion energy has existed for billions of years in the Sun, but its reproduction on Earth in a controlled and durable manner remains a challenge. Unlike fission, where atoms are split to produce energy, in fusion two lighter nuclei are joined together to make a heavier nucleus, while energy is released. In a controlled nuclear fusion power plant, three conditions must be fulfilled:

  • very high temperature (more than 10 times hotter than the centre of the Sun) to provoke highly energetic collisions at extreme speed,
  • sufficient particle density in the plasma – where the reaction takes place – to increase the probability of collisions, and
  • sufficient confinement to hold the plasma and allow the fusion reactions to take place continuously.

The most performing confinement concept to date has been the tokamak, a doughnut shaped configuration first invented in the 1950s, which uses powerful magnets to confine the plasma. By now, these machines can provide the essential conditions for fusion, in terms of both plasma density and the required temperature, and fusion power can be generated. This video visualizes the operation of a tokamak-based fusion reactor.

Building on ITER

The missing piece to producing net power remains better confinement, which is a measure of how good the magnetic field is at keeping the plasma energy, for which a bigger tokamak, such as ITER is needed. Afterwards, the technological challenges of bringing fusion power to the electricity grid will be addressed by a DEMO-type reactor. Individual countries are exploring ways to do this, and the IAEA is providing a platform for information sharing and exchange in order to facilitate the research and technology development.

China has made significant progress in planning for a device called China Fusion Engineering Test Reactor (CFETR) that would bridge the gaps between ITER and DEMO. Construction of the CFETR could start at around 2020 and be followed by construction of a DEMO in the 2030s.

The European Union and Japan are jointly building a powerful tokamak called JT-60SA in Naka, Japan, as a complement to ITER on a privileged partnership called the Broader Approach Activities. In addition to constructing the JT-60SA, the joint programme consists of two other projects, the Engineering Validation and Engineering Design Activities for the International Fusion Materials Irradiation Facility (IFMIF/EVEDA), and the International Fusion Energy Research Centre (IFERC). This partnership represents a well-integrated approach to support ITER and to prepare to undertake the engineering design and construction of a subsequent DEMO.

India has announced plans to begin building a device called SST-2 to develop components for a DEMO around 2027, and then start construction of a DEMO in 2037.

South Korea initiated a conceptual design study for a K-DEMO in 2012 targeting the construction by 2037 with potential for electricity generation starting in 2050. In its first phase (2037-2050), K-DEMO will develop and test components and then utilize these components in the second phase after 2050 to demonstrate net electricity generation.

Russia plans the development of a fusion-fission hybrid facility called DEMO fusion neutron source (FNS), a reactor that would harvest the fusion-produced neutrons to turn uranium into nuclear fuel and destroy radioactive waste. The DEMO-FNS is planned to be built by 2023, and is part of Russias’ fast-track strategy to a fusion power plant by 2050.

The United States of America is considering an intermediate step called Fusion Nuclear Science Facility (FNSF) to be used for the development and testing of fusion materials and components for a DEMO-type reactor. Plans call for operation to start after 2030, and construction of a DEMO after 2050.

Main findings and discussion carried out in the IAEA DEMO Programme Workshop series can be found here.

IAEA



8 Comments on "Charting the International Roadmap to a Demonstration Fusion Power Plant"

  1. Cloggie on Sat, 12th May 2018 11:31 am 

    21st century renewable
    22nd century fusion

  2. MASTERMIND on Sat, 12th May 2018 11:41 am 

    Clogg

    To many “if’s”….you fat sack of white shit…

  3. penury on Sat, 12th May 2018 12:03 pm 

    Fusion always twenty years away. The good news people make billions to keep hope alive.

  4. Cloggie on Sat, 12th May 2018 12:20 pm 

    To many “if’s”….you fat sack of white shit…

    http://tinyurl.com/y954o3nb

  5. Duncan Idaho on Sat, 12th May 2018 12:59 pm 

    “Fusion always twenty years away.”

    It is one of the few constants we have, like the speed of light.
    No matter when observed, be it 1950 or 2018, it is always a constant, 20 years away.

  6. onlooker on Sat, 12th May 2018 3:28 pm 

    Because all our dying civilization has left is false hope ie. Fusion

  7. dave thompson on Sat, 12th May 2018 11:02 pm 

    I always say even if humans can get one of these contraptions going say in the near future what then? How many would be needed to power industrial civ? How many, where and at what cost would these monstrosities be used in any practical sense?

  8. Go Speed Racer on Sun, 13th May 2018 6:11 am 

    If I put a penny and a quarter stacked together on the train tracks, the train comes thru and the two coins will become fused together. This is an example of
    fusion that works. But electrical energy from fusion ,
    that doesn’t work.

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