Name of the Project
International Thermonuclear Experimental Reactor (ITER) project.

Location
Cadarache, north of Marseille, southern France.

Project Owner/s
The ITER Organization, which includes China, the European Union (EU), India, Japan, Korea, Russia and the US.

Project Description
The ITER project is a large-scale scientific experiment that aims to demonstrate the feasibility of fusion as a large-scale and carbon-free source of energy.

The goal of ITER is to operate at 500 MW (for at least 400 seconds continuously), with 50 MW of plasma heating power input. No electricity will be generated at ITER.

The ITER is based on the Tokamak concept of magnetic confinement, in which the plasma is contained in a doughnut-shaped vacuum vessel.

Thirty-nine buildings and technical areas house the ITER Tokamak and its plant systems. The heart of the facility – the Tokamak building – is a seven-storey structure in reinforced concrete that is situated 13 ms below the platform level and 60 m above.

Other auxiliary buildings in the vicinity of the Tokamak building include cooling towers, electrical installations, a control room, facilities for the management of waste, and the cryogenics plant that will provide liquid helium to cool the ITER magnets.

The fuel for the reactor will be a mixture of two isotopes of hydrogen, deuterium and tritium, which will be heated to temperatures higher than 150-million degrees centigrade, forming the hot plasma.

The complex will be 80 m high, 120 m long and 80 m wide. Its footprint will be bigger than that of a football stadium.

It will rely on 493 plinths, equipped with antiseismic bearings. The plinths can sustain the overall weight of the reactor – about 23 000 t – almost three times the weight of the Eiffel Tower.

The complex will host 100 heavy nuclear and confinement doors. The major doors will be 4 m high, 4 m long and 35 cm thick. Each door will be about 40 t and they will be remotely operated. 

Almost 3 000 t of superconducting magnets will be connected by 200 km of superconducting cables, all kept at -269 ºC by the world’s biggest cryogenic plant.

Each building, once structurally complete, is handed over to the ITER Organization for the installation and assembly of equipment.

Potential Job Creation
An estimated 2 000 workers have participated in the construction of the ITER scientific facility.

Capital Expenditure
The project is valued at €23.6-billion. Members of the ITER Organization will bear the cost of the project through its ten-year construction phase and its 20-year operational phase before decommissioning. The project is mainly funded by the European Union (45.6%), with China, India, Japan, Korea, Russia and the US contributing 9.1% each.

Planned Start/End Date
First plasma at the ITER is planned for 2025, with deuterium/tritium fusion experiments starting in 2035.

Latest Developments
Mitsubishi Heavy Industries (MHI) has been awarded its first contract from Japan’s National Institutes for Quantum Science and Technology (QST) for the manufacture of six units of diverter outer vertical target components for ITER.

The outer vertical target is one of the parts in the diverter. MHI will handle the manufacturing of the first of a kind units (units 1 to 6, of a total of 54), with successive completion and delivery scheduled in fiscal 2024.

The diverter is one of the core components of the fusion reactor used in the Tokamak. It removes the helium ashes in the core plasma produced by the fusion reaction, unburned fuel and other impurities, as well as removes high heat load and particle loading, which are necessary for stable confinement of the plasma.

The diverter comprises four parts: the outer vertical target being procured by Japan, the cassette body and inner vertical target being manufactured in the European Union, and the dome being made in Russia.

The heat load in the diverter reaches a maximum of 20 MW/m², which is equivalent to the surface thermal load on an asteroid probe at re-entering into the atmosphere, and about 30 times the surface thermal load on the space shuttle. The outer vertical target, which structurally directly faces the fusion plasma, will be used in an extreme environment exposed to the heat load and particle loading from the plasma. In addition, the structure has an extremely complex shape, requiring leading edge manufacturing and machining technologies.

MHI previously awarded a contract from QST for the manufacture of five (of a total of 19) toroidal field coils, another core component of ITER. Four of these units have already been shipped, and are being installed in the device at the ITER site.

Key Contracts, Suppliers and Consultants
The VFR consortium, comprising Vinci Construction Grands Projets, Razel-Bec, Dodin Campenon Bernard, Campenon Bernard Sud-Est, GTM Sud, Chantiers Modernes Sud, Ferrovial Agroman and Assystem (final design Phase 1 and prototype testing of the diverter remote handling system); QST and MHI (toroidal field coils and manufacture of six units of diverter outer vertical target components for ITER); Italian Fincantieri Consortium, comprising Fincantieri, Fincantieri SI, Delta-ti Impianti and Comes (TCC1 assembly contract); META SNC, comprising France's Ponticelli Freres SAS and Spain's Cobra Instalaciones y Servicios SA and Empresarios Agrupados Internacional (TCC2 assembly contract); NIST (preliminary predevelopment and design of the HCCB TBS).

Contact Details for Project Information
ITER Organization communications, email itercommunications@iter.org.