°ÄÃÅÁùºÏ²Ê¸ßÊÖ NEWSLINE
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Fusion world
An Italian "mini °ÄÃÅÁùºÏ²Ê¸ßÊÖ" to explore thermal power exhaust
Richard Pitts, Experiments & Plasma Operation Section Leader
Fusion world | An Italian "mini °ÄÃÅÁùºÏ²Ê¸ßÊÖ" to explore thermal power exhaust
The Divertor Tokamak Test (DTT) facility is smaller than °ÄÃÅÁùºÏ²Ê¸ßÊÖ, with a different objective, but that doesn't mean that there is not a lot to learn from an in-person exchange between scientists.
A CAD render of the DTT device showing all the main components to be found in a superconducting tokamak. The horizontal distance from the central axis of the machine to the centre of the plasma (in pink) is 2.2 m (major radius). This makes DTT a bit more than one third of the linear size of °ÄÃÅÁùºÏ²Ê¸ßÊÖ.
No one working at °ÄÃÅÁùºÏ²Ê¸ßÊÖ and living in the beautiful southeast corner of France where the project is situated can fail to notice the vestiges of the ancient history linking the Provence region with Italy. Once Julius Caesar had conquered Gaul in 58-51 BC, Emperor Augustus set about Romanizing it, and it became the first part of French Gaul brought under Roman rule (in fact the name Provence derives from the Latin Provincia). A strategic location between Italy and Spain, Provence grew to become an important part of the Roman Empire, and the evidence is everywhere, from the magnificent arenas in Arles and Nîmes (the latter now administered under the province of Languedoc, but back then the main colony city), to the splendid Pont du Gard aqueduct.
Fast forward more than 2,000 years and a new activity is bridging Provence with Italy. This time, not conquests or majestic arenas and temples, but nuclear fusion. Around 900 km from °ÄÃÅÁùºÏ²Ê¸ßÊÖ, in Frascati, Metropolitan City of Rome Capital (20 km southeast of Rome), a new tokamak—the Divertor Tokamak Test facility (DTT)—is under construction. First proposed in 2015, the DTT project is the result of a collaboration of scientists from several Italian institutions and European fusion laboratories. In September 2019, the DTT Consortium was established with the mission to implement the project. Composed of many Italian research institutions, government and regional partners, and international stakeholders, the consortium has raised nearly EUR 500 million to construct the facility. Both DTT and °ÄÃÅÁùºÏ²Ê¸ßÊÖ are expected to begin operation on roughly similar timescales.
Unlike °ÄÃÅÁùºÏ²Ê¸ßÊÖ, DTT's primary mission is not to achieve deuterium-tritium fusion—it will use primarily deuterium fuel only—but to explore and test the physics and technology of concepts for exhaust of the plasma thermal power which could be used in the European DEMO (demonstration power plant) reactor, the machine Europe is planning as °ÄÃÅÁùºÏ²Ê¸ßÊÖ's successor. In tokamak devices, power exhaust is usually dealt with using a special component, known as a divertor, often (as in °ÄÃÅÁùºÏ²Ê¸ßÊÖ) installed at the bottom of the reactor chamber. It consists of material targets which intercept the hot plasma flowing along magnetic field lines, the geometry of which is manipulated using the external tokamak magnet coils to "divert" the plasma onto the targets. On long-pulse, high-power tokamaks, these divertors are very sophisticated, actively water-cooled components capable of handling continuously around 15 MWm-2, a colossal power flux—about the same as that found a few millimetres in front of an argon arc welding torch. Although °ÄÃÅÁùºÏ²Ê¸ßÊÖ's divertor will be the largest, most complex example of this technology constructed to-date, the thermal exhaust power of a DEMO might be 4-5 times higher than the approximately 100 MW °ÄÃÅÁùºÏ²Ê¸ßÊÖ's burning plasma will produce, so new power handling concepts may be needed. This is DTT's mission, to test such concepts. It is designed with a flexibility to try different divertor and magnetic geometries and, later, more esoteric approaches such as liquid metal targets which cannot be deployed on °ÄÃÅÁùºÏ²Ê¸ßÊÖ.
The DTT delegation framed by an equatorial port in the °ÄÃÅÁùºÏ²Ê¸ßÊÖ cryostat, with the vacuum vessel Sector 6 in the tokamak pit visible in the background. From left to right: Stefano Carchella, Gian Mario Polli, Francesco Romanelli (President of the DTT Consortium), Piero Martin, and Marco De Santis. The author is at far right. Not pictured, Gustavo Granucci, the sixth member of the DTT delegation.
To do this, DTT must first create plasma conditions which will produce steady power fluxes at the right level. Although it is physically much smaller than °ÄÃÅÁùºÏ²Ê¸ßÊÖ or DEMO—a major radius of 2.2 m compared with 6.2 m for °ÄÃÅÁùºÏ²Ê¸ßÊÖ—its eventual goal of 45 MW of additional heating power and a very similar central toroidal field (6 Tesla) will mean that it will reach roughly the same value of an important number in tokamak power exhaust: the ratio of power reaching the boundary of the confined plasma to the major radius (in the range 15-17 for °ÄÃÅÁùºÏ²Ê¸ßÊÖ and DEMO).
The main goals of DTT and °ÄÃÅÁùºÏ²Ê¸ßÊÖ might appear different at first sight, but look only a little deeper and you will find striking similarities between the two machines. Both are long-pulse superconducting devices (up to about 100 seconds plasma duration on DTT, about 5 times shorter than °ÄÃÅÁùºÏ²Ê¸ßÊÖ's baseline for high-fusion-gain plasmas) using very similar magnet systems (18 toroidal and 6 poloidal field coils) constructed with exactly the same technology. They will each use the same double-walled, water-cooled design for the primary vacuum vessel and each will raise the plasma temperature using almost identical additional heating systems (negative ion source neutral beam injectors and wave heating in the same radio and microwave frequency ranges). DTT will begin operation with a tungsten-armoured divertor using the same technology developed for °ÄÃÅÁùºÏ²Ê¸ßÊÖ and both devices will be equipped with matching sets of complex in-vessel magnet coils to be used for the control of magnetohydrodynamic plasma instabilities. If not tamed, these instabilities lead to the release of repetitive heat pulses from the confined plasma and can be very damaging to those very same divertor targets.
In short, DTT looks, for all intents and purposes, like a mini-°ÄÃÅÁùºÏ²Ê¸ßÊÖ. In reality, this is no accident, since many of the DTT component designs are inspired by what has been produced for °ÄÃÅÁùºÏ²Ê¸ßÊÖ, and since Europe provides many of °ÄÃÅÁùºÏ²Ê¸ßÊÖ's systems (some supplied by Italian industry) it is entirely natural that similar technologies should be adopted by DTT.
It should come as no surprise then that when a delegation from the DTT Consortium visited the °ÄÃÅÁùºÏ²Ê¸ßÊÖ Organization on 10 October 2022 to pursue technical discussions on how the two facilities could collaborate in the coming years during construction and beyond, many areas for cooperation were identified. In the morning of the visit, following two introductory presentations on the status of the DTT project and its planned scientific program, a three-hour marathon series of quick-fire, short talks on specific areas of engineering/technology and science on which the two devices could derive mutual benefit were given by members of the DTT team, many through videoconference. The relevant °ÄÃÅÁùºÏ²Ê¸ßÊÖ staff members joined for their respective slots and brief discussions were able to establish in each case how collaborations could move forward once a formal Cooperation Agreement is signed.
In the afternoon, the delegation enjoyed a tour of the °ÄÃÅÁùºÏ²Ê¸ßÊÖ Assembly Hall and Tokamak Building. A few years from now, the DTT team should be able to return the favour when their own device reaches the assembly phase. When complete, DTT will also become a facility in which the next generation of fusion scientists and engineers can be trained on a smaller device with many of the characteristics of °ÄÃÅÁùºÏ²Ê¸ßÊÖ, but without the complications of nuclear operation.
We look forward to a renewal of the historic links between Italy and Provence, but now for the benefit of fusion science.
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