* Astronomy

A new type of high-frequency ion source developed at Max Planck Institute of Plasma Physics (IPP) in Garching near Munich has been chosen to heat the plasma of the ITER fusion test device. This was now decided, after a unanimous recommendation was made by the international body of experts responsible for changes of plan. "For IPP this is a great success crowning many years of development work", as division head Dr. Eckehart Speth was happy to announce.

The ITER (Latin for "the way") test device is the next major step in international fusion research. Construction of the device is to commence at Cadarache, France, in the coming year in a cooperation comprising seven partners Europe, Japan, USA, Russia, China, India and South Korea. With a generated fusion power of 500 megawatts ten times as much as will be needed to heat the plasma beforehand ITER is to demonstrate that an energy-yielding fusion fire is possible.

Like the sun, a fusion power plant is to derive energy from fusion of atomic nuclei. For this purpose the fuel an ionised low-density gas, a "plasma" has to be successfully confined in a magnetic field cage without touching the vessel wall and heated to temperatures of over 100 million degrees. In ITER about half of this is to be accomplished with "neutral particle heating": Fast hydrogen atoms injected into the plasma transfer their energy to the plasma particles on colliding with them. Todays devices can thus attain many times the suns temperature at the press of a button. The ITER large-scale device, however, imposes new requirements on the established procedure: For example, the particles have to be three to four times faster than hitherto so that they can penetrate deep enough into the voluminous plasma.
In view of these increased requirements the heating method developed at IPP affords appreciable advantages over the solutions available to date. The new source an achievement for which the team around Dr. Speth was awarded the Erwin Schrödinger Prize of the Helmholtz Association in 2006 is, for example, particularly robust and needs little maintenance. Since 2002 IPP has been further developing the original version of the source, successfully operated in IPPs ASDEX Upgrade experiment since 1995, to make it satisfy ITERs requirements. The results achieved on three test rigs at IPP have now convinced the ITER team: "New technique takes time to assert itself", as Dr. Speth puts it. But the development work has not come to an end with the decision now taken. A further test rig for a source half the size of that for ITER is to be built shortly at IPP. This is to check whether the particle beam can meet the requirements for ITER. The system in the original size is then to be investigated by Italys ENEA fusion institute at Padua.

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A $12 billion worldwide attempt to generate power from nuclear fusion was signed into existence today by ministers from the project's seven international partners--China, the European Union, India, Japan, Korea, Russia, and the United States. The International Thermonuclear Experimental Reactor (ITER) project has been 2 decades in the making, and with today's signing, construction of the reactor in southern France can begin next year.

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France has been awarded the contract to build the 10 billion-euro nuclear fusion reactor, in the face of strong competition from Japan.

The International Thermonuclear Experimental Reactor (Iter) will be the most expensive joint scientific project after the International Space Station.
The Iter programme was held up for over 18 months as parties tried to broker a deal between the two rivals.

"[i[It is a big success for France, for Europe and for all the partners of Iter" - statement issued by the office of French President Jacques Chirac.