2003
DOI: 10.1088/0029-5515/43/12/008
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An overview of results from the TCV tokamak

Abstract: The Tokamak à Configuration Variable (TCV) tokamak (R = 0.88 m, a < 0.25 m, B < 1.54 T) programme is based on flexible plasma shaping and heating for studies of confinement, transport, control and power exhaust. Recent advances in fully sustained off-axis electron cyclotron current drive (ECCD) scenarios have allowed the creation of plasmas with high bootstrap fraction, steady-state reversed central shear and an electron internal transport barrier. High elongation plasmas, κ = 2.5, are produced at low normaliz… Show more

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Cited by 29 publications
(20 citation statements)
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“…ions with energies much larger than the background plasma. These can be generated by coherent or turbulent acceleration mechanisms or by shocks (Reames 1999;Perri and Zimbardo 2012), or directly by external sources (neutral beams and/or EC resonance heating (ECRH and current drive (CD), (Goodman et al 2003;Henderson et al 2003)) or nuclear reactions, as in the case of magnetic fusion devices. Common to all of these systems is the question of how plasma turbulence influences suprathermal particles and, in turn, how suprathermal particles influence turbulence.…”
Section: Suprathermal Ion Physicsmentioning
confidence: 99%
“…ions with energies much larger than the background plasma. These can be generated by coherent or turbulent acceleration mechanisms or by shocks (Reames 1999;Perri and Zimbardo 2012), or directly by external sources (neutral beams and/or EC resonance heating (ECRH and current drive (CD), (Goodman et al 2003;Henderson et al 2003)) or nuclear reactions, as in the case of magnetic fusion devices. Common to all of these systems is the question of how plasma turbulence influences suprathermal particles and, in turn, how suprathermal particles influence turbulence.…”
Section: Suprathermal Ion Physicsmentioning
confidence: 99%
“…The dependence of the suprathermal population on the toroidal injection angle is clearly demonstrated by figure 1, which shows the effect of sweeping during a plasma discharge on two out of three launchers: while the bulk temperature and the lower energy HXR signal remain constant, the high-energy HXR emission and the ECE radiative temperature increase rapidly with [19]. This example also illustrates the high degree of external control of multiple deposition locations and toroidal injection angles available on TCV, which has proven instrumental in the application of ECCD to current and pressure profile tailoring [5][6][7][20][21][22].…”
Section: Eccd and Suprathermal Electronsmentioning
confidence: 99%
“…The TCV tokamak (R = 0.88 cm, a = 0.25 cm, I p 1 MA, B φ 1.54 T) is equipped with a 4.5 MW EC heating system, powered by six second harmonic (X2, 82.7 GHz) and three third harmonic (X3, 118 GHz) 0.5 MW gyrotrons. An extremely flexible EC beam delivery system, allowing real-time poloidal and toroidal steering, matches the equally flexible plasma position and shape control system of TCV [5].…”
Section: Introductionmentioning
confidence: 99%
“…The ECRH delivery system provides unique flexibility: the second-harmonic system at 82.7 GHz consists of six 0.45 MW beams delivered by six independent launchers, which can be steered in real time to provide either pure heating or cocurrent and countercurrent drive ͑ECCD͒ simultaneously at different locations within the plasma. 16 An equally flexible control system, based on 16 independently powered shaping coils, permits the control of extremely varied plasma shapes and positions within the vacuum chamber ͑elongation 0.9 ഛ ഛ 2.8, triangularity −0.6ഛ ␦ ഛ + 0.9͒. The main plasma parameters are as follows: major radius R = 0.88 cm, minor radius a = 0.25 cm, plasma current I p ഛ 1 MA, toroidal magnetic field B ഛ 1.54 T, total ECRH power ͑second and third harmonic, 82.7 and 118 GHz, respectively͒ P EC = 4.5 MW.…”
Section: Introductionmentioning
confidence: 99%