D-T Fusion with Ion Cyclotron Resonance Heating in the JET Tokamak

Start, D.F.H.; Jacquinot, J.; Bergeaud, V.; Bhatnagar, V.P.; Cottrell, Geoff; Clement, S.; Eriksson, L.‐G.; Fasoli, A.; Gondhalekar, A.; Gormezano, C.; Grosshoeg, G.; Guenther, Karl H.; Harbour, P.J.; Horton, L. D.; Howman, A.; Jäckel, H.; Jarvis, O.N.; Lawson, K.; Lowry, C.; Mantsinen, M.; Marcus, F.B.; Monk, R.D.; Righi, E.; Rimini, F.; Sadler, G.; Saibene, G.; Sartori, R.; Schunke, B.; Sharapov, S. E.; Sips, A. C. C.; Stamp, M.; Belle, P. van

doi:10.1103/physrevlett.80.4681

Cited by 93 publications

(66 citation statements)

References 12 publications

(6 reference statements)

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“…Neutron spectrometer measurements show a Doppler broadening [8] commensurate with T i = 13.5 ± 2.5 keV in good agreement with the charge exchange measurement. Similar results were achieved with 6.5%…”

Section: Optimised Experimentssupporting

confidence: 70%

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Bulk ion heating with ICRH in JET DT plasmas

Start¹,

Jacquinot

Bergeaud

et al. 1999

Nucl. Fusion

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ABSTRACT.Reactor relevant ICRH scenarios have been assessed during D-T experiments on the JET tokamak using H-mode divertor discharges with ITER-like shapes and safety factors. Deuterium minority heating in tritium plasmas was demonstrated for the first time. For 9% deuterium, an ICRH power of 6 MW gave 1.66 MW of fusion power from reactions between suprathermal deuterons and thermal tritons. The Q-value of the steady state discharge reached 0.22 for the length of the RF flat top (2.7 s), corresponding to three plasma energy replacement times. The Doppler broadened neutron spectrum showed a deuteron energy of 125 keV which was optimum for fusion and close to the critical energy. Thus strong bulk ion heating was obtained at the same time as high fusion efficiency. Deuterium fractions around 20% produced the strongest ion heating together with a strong reduction of the suprathermal deuteron tail. The edge localised modes (ELMs) had low amplitude and high frequency and each ELM transported less plasma energy content

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Section: Optimised Experimentssupporting

confidence: 70%

“…Redistribution of the fast ions by sawteeth, as observed experimentally [8], is also included. The predicted fusion reactivity is in excellent agreement with the observed reactivity [13].…”

Section: Maximum Fusion Reactivitymentioning

confidence: 99%

Bulk ion heating with ICRH in JET DT plasmas

Start¹,

Jacquinot

Bergeaud

et al. 1999

Nucl. Fusion

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“…A smaller FNSF, however, can produce fusion neutrons via NBI driven beam-target reactions in a similar manner to the TFTR/JET DT experiments. 71,72 To achieve the plasma parameters necessary for a FNSF, one may need plasma pressure (n T) or B Fig. 31, B T0 2 b T is plotted as a function of R 0 (as a measure of the achievable plasma pressure) for possible FNSF parameters: A ¼ 1.6, q* ¼ 3, and j ¼ 3, and a relatively modest beta of b N ¼ 3 at the two gap distances of D ¼ 0 and 10 cm.…”

mentioning

confidence: 99%

Recent progress on spherical torus research

Ono

Kaita

2015

Physics of Plasmas

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The spherical torus or spherical tokamak (ST) is a member of the tokamak family with its aspect ratio (A = R0/a) reduced to A ∼ 1.5, well below the normal tokamak operating range of A ≥ 2.5. As the aspect ratio is reduced, the ideal tokamak beta β (radio of plasma to magnetic pressure) stability limit increases rapidly, approximately as β ∼ 1/A. The plasma current it can sustain for a given edge safety factor q-95 also increases rapidly. Because of the above, as well as the natural elongation κ, which makes its plasma shape appear spherical, the ST configuration can yield exceptionally high tokamak performance in a compact geometry. Due to its compactness and high performance, the ST configuration has various near term applications, including a compact fusion neutron source with low tritium consumption, in addition to its longer term goal of an attractive fusion energy power source. Since the start of the two mega-ampere class ST facilities in 2000, the National Spherical Torus Experiment in the United States and Mega Ampere Spherical Tokamak in UK, active ST research has been conducted worldwide. More than 16 ST research facilities operating during this period have achieved remarkable advances in all fusion science areas, involving fundamental fusion energy science as well as innovation. These results suggest exciting future prospects for ST research both near term and longer term. The present paper reviews the scientific progress made by the worldwide ST research community during this new mega-ampere-ST era.

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“…[18] However, experiments indicate that the elevated plasma potentials and poor heating efficiency is due to poor wave penetration to the plasma core. We performed a series of discharges where the heating scenario is mode conversion heating and the minority 3 He concentration is ~15%. The majority of the launched power is absorbed on electrons.…”

Section: Dipole Versus Monopolementioning

confidence: 99%

“…This derives, in part, from the fact that ICRF has been experimentally demonstrated to heat high performance plasmas in a number of experiments including deuterium-tritium discharges on TFTR [2] and JET [3], and has favorable scaling to burning plasmas. Unlike the previous generation of fusion experiments, the plasma facing components (PFCs) for future reactors and a growing number of experiments are high Z metals, [AUG, JET, C-Mod], due to concerns regarding material erosion and tritium retention with carbon.…”

Section: Introductionmentioning

confidence: 99%

Assessment of a field-aligned ICRF antenna

Wukitch¹,

Brunner²,

Ennever³

et al. 2014

AIP Conference Proceedings

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Abstract. Impurity contamination and localized heat loads associated with ion cyclotron range of frequency (ICRF) antenna operation are among the most challenging issues for ICRF utilization.. Another challenge is maintaining maximum coupled power through plasma variations including edge localized modes (ELMs) and confinement transitions. Here, we report on an experimental assessment of a field aligned (FA) antenna with respect to impurity contamination, impurity sources, RF enhanced heat flux and load tolerance. In addition, we compare the modification of the scrape of layer (SOL) plasma potential of the FA antenna to a conventional, toroidally aligned (TA) antenna, in order to explore the underlying physics governing impurity contamination linked to ICRF heating. The FA antenna is a 4-strap ICRF antenna where the current straps and antenna enclosure sides are perpendicular to and the Faraday screen rods are parallel to the total magnetic field. In principle, alignment with respect to the total magnetic field minimizes integrated E|| (electric field along a magnetic field line) via symmetry. Consistent with expectations, we observed that the impurity contamination and impurity source at the FA antenna are reduced compared to the TA antenna. In both L and H-mode discharges, the radiated power is 20-30% lower for a FA-antenna heated discharge than a discharge heated with the TA-antennas. Further we observe that the fraction of RF energy deposited upon the antenna is less than 0.4 % of the total injected RF energy in dipole phasing. The total deposited energy increases significantly when the FA antenna is operated in monopole phasing. The FA antenna also exhibits an unexpected load tolerance for ELMs and confinement transitions compared to the TA antennas. However, inconsistent with expectations, we observe RF induced plasma potentials to be nearly identical for FA and TA antennas when operated in dipole phasing. In monopole phasing, the FA antenna has the highest plasma potentials and poor heating efficiency despite calculations indicating low integrated E||. In mode conversion heating scenario, no core waves were detected in the plasma core indicating poor wave penetration. For monopole phasing, simulations suggest the antenna spectrum is peaked at very short wavelength and full wave simulations show the short wavelength has poor wave penetration to the plasma core.

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D-T Fusion with Ion Cyclotron Resonance Heating in the JET Tokamak

Cited by 93 publications

References 12 publications

Bulk ion heating with ICRH in JET DT plasmas

Bulk ion heating with ICRH in JET DT plasmas

Recent progress on spherical torus research

Assessment of a field-aligned ICRF antenna

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