Your search keyword '"Challis C.D."' showing total 6 results

1. Experiments in high-performance JET plasmas in preparation of second harmonic ICRF heating of tritium in ITER.

Author

Mantsinen, M.J., Jacquet, P., Lerche, E., Gallart, D., Kirov, K., Mantica, P., Taylor, D., Van Eester, D., Baruzzo, M., Carvalho, I., Challis, C.D., Dal Molin, A., Delabie, E., De La Luna, E., Dumont, R., Dumortier, P., Eriksson, J., Frigione, D., Garcia, J., and Garzotti, L.

Subjects

NEUTRAL beams, PLASMA jets, PLASMA beam injection heating, CYCLOTRON resonance, TRITIUM, HEATING, FAST Fourier transforms

Abstract

The reference ion cyclotron resonance frequency (ICRF) heating schemes for ITER deuterium–tritium (D-T) plasmas at the full magnetic field of 5.3 T are second harmonic heating of T and 3He minority heating. The wave-particle resonance location for these schemes coincide and are central at a wave frequency of 53 MHz at 5.3 T. Experiments have been carried out in the second major D-T campaign (DTE2) at JET, and in its prior D campaigns, to integrate these ICRF scenarios in JET high-performance plasmas and to compare their performance with the commonly used hydrogen (H) minority heating. In 50:50 D:T plasmas, up to 35% and 5% larger fusion power and diamagnetic energy content, respectively, were obtained with second harmonic heating of T as compared to H minority heating at comparable total input powers and gas injection rates. The core ion temperature was up to 30% and 20% higher with second harmonic T and 3He minority heating, respectively, with respect to H minority heating. These are favourable results for the use of these scenarios in ITER and future fusion reactors. According to modelling, adding ICRF heating to neutral beam injection using D and T beams resulted in a 10%–20% increase of on-axis bulk ion heating in the D-T plasmas due to its localisation in the plasma core. Central power deposition was confirmed with the break-in-slope and fast Fourier transform analysis of ion and electron temperature in response to ICRF modulation. The tail temperature of fast ICRF-accelerated tritons, their enhancement of the fusion yield and time behaviour as measured by an upgraded magnetic proton recoil spectrometer and neutral particle analyser were found in agreement with theoretical predictions. No losses of ICRF-accelerated ions were observed by fast ion detectors, which was as expected given the high plasma density of n e ≈ 7–8 × 1019 m−3 in the main heating phase that limited the formation of ICRF-accelerated fast ion tails. 3He was introduced in the machine by 3He gas injection, and the 3He concentration was measured by a high-resolution optical penning gauge in the sub-divertor region. The DTE2 experiments with 3He minority heating were carried with a low 3He concentration in the range of 2%–4% given the fact that the highest neutron rates with 3He minority heating in D plasmas were obtained at low 3He concentrations of ∼2%, which also coincided with the highest plasma diamagnetic energy content. In addition to 3He introduced by 3He gas injection, an intrinsic concentration of 3He of the order of 0.2%–0.4% was measured in D-T plasmas before 3He was introduced in the device, which is attributed to the radioactive decay of tritium to 3He. According to modelling, even such low intrinsic concentrations of 3He lead to significant changes in ICRF power partitioning during second harmonic heating of T due to absorption of up to 30% of the wave power by 3He. [ABSTRACT FROM AUTHOR]

Published

2023

2. Tritium neutral beam injection on JET: calibration and plasma measurements of stored energy.

Author

King, D.B., Sharma, R., Challis, C.D., Bleasdale, A., Delabie, E.G., Douai, D., Keeling, D., Lerche, E., Lennholm, M., Mailloux, J., Matthews, G., Nicassio, M., Štancar, Ž., and Wilson, T.

Subjects

PLASMA jets, NEUTRAL beams, TRITIUM, PLASMA beam injection heating, INJECTIONS, ALPHA rays, TOKAMAKS, DEUTERIUM

Abstract

Neutral beam injection (NBI) is a flexible auxiliary heating method for tokamak plasmas, capable of being efficiently coupled to the various plasma configurations required in the Tritium and mixed deuterium-tritium experimental campaign on the Joint European Torus (JET) device. High NBI power was required for high fusion yield and alpha particle studies and to provide mixed deuterium-tritium (D-T) fuelling in the plasma core, it was necessary to operate the JET NBI systems in both deuterium and tritium. Further, the pure tritium experiments performed required T NBI for high isotopic purity and reduced 14 MeV neutron yield. Accurate power calibrations are also essential to machine safety. Previously on JET there have been a number of questions raised on the NBI power calibration, in particular following the Trace Tritium Experiments (TTEs). Operator activities on the tokamak NBI system, including calibrations, were performed in 2020. Following these activities, a series of plasma experiments were devised to further corroborate the T NBI power by comparing the plasma response to the D NBI power. A series of stationary, L-mode plasmas were performed on JET with different beam combinations used in different phases of the same pulse. By comparing the plasma response for D and T NBI it was possible to corroborate the T NBI power calibration using the D NBI power calibration. The stored energy as measured by magnetic diagnostics, corrected for fast particle stored energy, show that the uncertainty in NBI power calibration in T is comparable to that in D. [ABSTRACT FROM AUTHOR]

Published

2023

3. JET D-T scenario with optimized non-thermal fusion.

Author

Maslov, M., Lerche, E., Auriemma, F., Belli, E., Bourdelle, C., Challis, C.D., Chomiczewska, A., Dal Molin, A., Eriksson, J., Garcia, J., Hobirk, J., Ivanova-Stanik, I., Jacquet, Ph., Kappatou, A., Kazakov, Y., Keeling, D.L., King, D.B., Kiptily, V., Kirov, K., and Kos, D.

Subjects

THERMAL plasmas, NEUTRAL beams, TRITIUM, ELECTROMAGNETIC waves, FAST ions, NUCLEAR fusion, ION acoustic waves

Abstract

In JET deuterium-tritium (D-T) plasmas, the fusion power is produced through thermonuclear reactions and reactions between thermal ions and fast particles generated by neutral beam injection (NBI) heating or accelerated by electromagnetic wave heating in the ion cyclotron range of frequencies (ICRFs). To complement the experiments with 50/50 D/T mixtures maximizing thermonuclear reactivity, a scenario with dominant non-thermal reactivity has been developed and successfully demonstrated during the second JET deuterium-tritium campaign DTE2, as it was predicted to generate the highest fusion power in JET with a Be/W wall. It was performed in a 15/85 D/T mixture with pure D-NBI heating combined with ICRF heating at the fundamental deuterium resonance. In steady plasma conditions, a record 59 MJ of fusion energy has been achieved in a single pulse, of which 50.5 MJ were produced in a 5 s time window (P fus = 10.1 MW) with average Q = 0.33, confirming predictive modelling in preparation of the experiment. The highest fusion power in these experiments, P fus = 12.5 MW with average Q = 0.38, was achieved over a shorter 2 s time window, with the period of sustainment limited by high-Z impurity accumulation. This scenario provides unique data for the validation of physics-based models used to predict D-T fusion power. [ABSTRACT FROM AUTHOR]

Published

2023

4. Analysis of the fusion performance, beam–target neutrons and synergistic effects of JET's high-performance pulses.

Author

Kirov, K.K., Belonohy, E., Challis, C.D., Eriksson, J., Frigione, D., Garzotti, L., Giacomelli, L., Hobirk, J., Kappatou, A., Keeling, D., King, D., Lerche, E., Lomas, P.J., Nocente, M., Reux, C., Rimini, F.G., Sips, A.C.C., Van Eester, D., and Contributors, JET

Subjects

NEUTRONS, PLASMA beam injection heating, NUCLEAR fusion, FAST ions, ELECTRON impact ionization, NEUTRAL beams, ION temperature

Abstract

Achieving high neutron yields in today's fusion research relies on high-power auxiliary heating in order to attain required core temperatures. This is usually achieved by means of high neutral beam (NB) and radio frequency (RF) power. Application of NB power is accompanied by production of fast beam ions and associated beam–target (BT) reactions. In standard JET operational conditions, deuterium (D) NBs are injected into D plasmas. The injected beams comprise D atoms at full, one-half and one-third injected energy. Typically, the full energy of the injected D beams is between 90 and 120 keV, providing 1.4–2.0 MW of heating, which is about half of the injected power. Half-energy D beams carry about one-third of the injected power and the rest of the power is carried by the third energy fraction of D beams. Under these conditions, thermal fusion reactions, i.e. those between plasma ions, and BT reactions are of the same order of magnitude. This study addresses important issues regarding the impact of density, central electron and ion temperatures and their ratio, Ti(0)/Te(0), on fusion performance, measured by the total neutron yield and BT neutron counts. NB/RF synergistic effects are discussed as well. It is demonstrated that thermal fusion gain increases linearly with normalised plasma pressure, βN, and confinement, Btτ. The BT neutrons are, however, more difficult to predict and this task in general requires numerical treatment. In this study, BT neutrons in JET's best-performing baseline and hybrid pulses are analysed and the underlying dependencies discussed. Central fast ion densities are found to decrease with increased density and density peaking. This is attributed to poorer beam penetration at high density. The BT reactions however are unchanged and can even increase if operating at higher core temperatures. An increase in the central ion temperature and Ti(0)/Te(0) ratio leads to higher total and BT reaction rates whilst simultaneously the ratio of the BT to total neutron decreases significantly. NB/RF synergistic effects are found to have a negligible impact on total neutron rate. This can be explained by the reduced beam penetration in high-density conditions leading to lower central fast ion density. [ABSTRACT FROM AUTHOR]

Published

2021

5. Measurement of the depletion of neutraliser target due to gas heating in the JET neutral beam injection system

Author

Surrey, E., Challis, C.D., Ciric, D., Cox, S.J., Crowley, B., Jenkins, I., Jones, T.T.C., and Keeling, D.

Subjects

*NEUTRALIZATION (Chemistry), *NEUTRAL beams, *ION bombardment, *HEATING

Abstract

Abstract: The reduction in neutralisation efficiency of positive ion beams compared to theoretical calculations has been acknowledged for some time. The effect has been ascribed to a depletion of the gas target in the neutraliser, although the cause of this has been the subject of debate. Recent measurements in the neutraliser of the JET neutral beam injection (NBI) system showed a significant increase of the gas temperature, supporting the gas heating hypothesis. This work presents direct measurement, by two methods, of the power contained in the neutral component of the JET neutral beam injection system that confirms the neutralisation shortfall. A calorimetric technique is used to compare the power within the full (i.e. ions and neutrals) and neutral beam components for the high current JET triode injectors, from which the effective gas target can be derived. The results of these measurements are confirmed by considering the response to neutral beam injection of the energy stored in the tokamak plasma. Finally, the gas heating model, combined with earlier measurements of the gas temperature in the neutraliser, is used to support the hypothesis that the target depletion is due to indirect heating of the neutraliser gas by the beam. [Copyright &y& Elsevier]

Published

2005

6. Overview of the JET neutral beam enhancement project

Author

Ćirić, D., Brown, D.P.D., Challis, C.D., Chuilon, B., Cox, S.J., Crowley, B., Day, I.E., Edwards, D.C., Evison, G., Hackett, L.J., Hotchin, S., Hudson, Z., Jenkins, I., Jones, T.T.C., King, R., Kovari, M., Martin, D., Milnes, J., Parkin, A., and Puma, A. Li

Subjects

*CONTROLLED fusion, *PUMPING machinery, *ELECTRICAL engineering, *HIGH voltages

Abstract

Abstract: The JET neutral beam (NB) heating system is being upgraded as a part of the ongoing JET Enhancement Programme. This is one of the largest upgrades of the JET machine carried out within the EFDA-JET framework. The main goals of the project are to increase the NB power delivered to JET plasma, to increase the beam pulse duration and to improve the availability and reliability of the JET NB system. The upgrade of the system is being carried out through the modification of the two existing neutral injector boxes (NIBs), each equipped with up to eight positive ion neutral injectors (PINIs). Significant changes of the JET NB system will be carried out within the next few years and will include modification of all PINIs, modification or replacement of various beamline components and corresponding instrumentation, procurement and installation of new high voltage power supply (HVPS) units and corresponding control systems and refurbishment of the 36kV power distribution. Various physics, engineering and planning issues related to this project, as well as the current status of the project are discussed in detail. Particular attention is given to the results of a PINI prototype test, which are of crucial importance for the successful completion of the entire enhancement programme. Upon the completion of the project in 2009/2010, JET NB system should be capable of delivering more than 34MW of deuterium beam power into the JET plasma for a duration of up to 20s with improved reliability. This will significantly enhance overall capabilities of the JET machine in support of ITER development. [Copyright &y& Elsevier]

Published

2007