Your search keyword '"M. Gorelenkova"' showing total 28 results

1. Analysis of fusion alphas interaction with RF waves in D-T plasma at JET

Author

K.K. Kirov, F. Auriemma, P.J. Bonofiglo, C.D. Challis, E. De la Luna, J. Eriksson, D. Gallart, J. Garcia, M. Gorelenkova, J. Hobirk, P. Jacquet, A. Kappatou, Y. Kazakov, D. Keeling, D. King, V. Kiptily, E. Lerche, C. Maggi, J. Mailloux, P. Mantica, M. Mantsinen, M. Maslov, S. Menmuir, R. Sharma, P. Siren, Z. Stancar, D. Van Eester, and JET Contributors

Subjects

JET, DT plasma, alphas, synergistic effects, ICRH, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

This work studies the influence of radio frequency (RF) waves in the ion cyclotron resonance heating (ICRH) range of frequencies on fusion alphas during the recent JET D-T campaign. Fusion alphas from D-T reactions are created with energies of about 3.5 MeV and therefore have significant Doppler shifts enabling synergistic interactions between them and RF waves at a broad range of frequencies, including the ones foreseen for future fusion machines in ITER (Schneider et al 2021 Nucl. Fusion 61 126058) and SPARC (Creely et al 2020 J. Plasma Phys. 86 865860502). Resonant interactions between RF waves and alphas, also called synergistic effects, will modify the alpha distribution and ultimately will have an impact on alpha orbit losses and heating. Data from JET 3.43 T/2.3 MA pulses based on the hybrid scenario (Hobirk et al 2023 Nucl. Fusion ; Hobirk et al 29th IAEA FEC23 Conf. ( 16–21 October 2023 ); Challis et al 48th EPS Conf. on Plasma Physics ( 27 June–1 July 2022 ) during the DTE2 campaign (Maggi et al 2023 Nucl. Fusion )) were used for the analysis in this study. The impact of synergistic effects on alpha orbit losses and alpha heating are assessed. The conclusions are based on the analysis of experimental data for fast alpha losses, i.e. measurements from neutral particle analyser (NPA), fast ion losses scintillator detector, Faraday cups (FCs), and TRANSP (Hawryluk et al 1980 Physics of Plasmas Close to Thermonuclear Conditions vol 1 (CEC) pp 19–46) simulations. Experimental data and TRANSP analysis indicates that there are indeed changes in the alpha distribution function (DF) due to interaction with RF waves. Data from the NPA show increased ^4 He flux in the range from a few hundred keV up to 800 keV for pulses with RF power, while TRANSP clearly shows modifications in the fast alpha DF for these energies. Data from the scintillator detector and the FCs were compared for pulses with and without ICRH power and versus cases with enhanced alpha losses due to MHD activity. The trends from these diagnostics consistently show no additional alpha losses due to interaction with RF waves. TRANSP predictions for the impact of ynergistic effects on alpha heating show up to a 42% increase in alpha electron heating and up to a 25% increase in alpha ion heating. These effects, however, become negligibly small, less than 1%, when alpha heating is compared to the total auxiliary heating power in the investigated JET pulses.

Published

2024

2. Overview of interpretive modelling of fusion performance in JET DTE2 discharges with TRANSP

Author

Ž. Štancar, K.K. Kirov, F. Auriemma, H.-T. Kim, M. Poradziński, R. Sharma, R. Lorenzini, Z. Ghani, M. Gorelenkova, F. Poli, A. Boboc, S. Brezinsek, P. Carvalho, F.J. Casson, C.D. Challis, E. Delabie, D. Van Eester, M. Fitzgerald, J.M. Fontdecaba, D. Gallart, J. Garcia, L. Garzotti, C. Giroud, A. Kappatou, Ye.O. Kazakov, D.B. King, V.G. Kiptily, D. Kos, E. Lerche, E. Litherland-Smith, C.F. Maggi, P. Mantica, M.J. Mantsinen, M. Maslov, S. Menmuir, M. Nocente, H.J.C. Oliver, S.E. Sharapov, P. Sirén, E.R. Solano, H.J. Sun, G. Szepesi, and JET Contributors

Subjects

deuterium-tritium plasma, integrated modelling, fusion performance, JET, TRANSP, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

In the paper we present an overview of interpretive modelling of a database of JET-ILW 2021 D-T discharges using the TRANSP code. The main aim is to assess our capability of computationally reproducing the fusion performance of various D-T plasma scenarios using different external heating and D-T mixtures, and to understand the performance driving mechanisms. We find that interpretive simulations confirm a general power-law relationship between increasing external heating power and fusion output, which is supported by absolutely calibrated neutron yield measurements. A comparison of measured and computed D-T neutron rates shows that the calculations’ discrepancy depends on the absolute neutron yield. The calculations are found to agree well with measurements for higher performing discharges with external heating power above ∼20 $\mathrm{MW}$ , while low-neutron shots display an average discrepancy of around +40% compared to measured neutron yields. A similar trend is found for the ratio between thermal and beam-target fusion, where larger discrepancies are seen in shots with dominant beam-driven performance. We compare the observations to studies of JET-ILW D discharges, to find that on average the fusion performance is well modelled over a range of heating power, although an increased unsystematic deviation for lower-performing shots is observed. The ratio between thermal and beam-induced D-T fusion is found to be increasing weakly with growing external heating power, with a maximum value of $\gtrsim$ 1 achieved in a baseline scenario experiment. An evaluation of the fusion power computational uncertainty shows a strong dependence on the plasma scenario type and fusion drive characteristics, varying between ±25% and 35%. D-T fusion alpha simulations show that the ratio between volume-integrated electron and ion heating from alphas is $\lesssim$ 10 for the majority of analysed discharges. Alphas are computed to contribute between ∼15% and 40% to the total electron heating in the core of highest performing D-T discharges. An alternative workflow to TRANSP was employed to model JET D-T plasmas with the highest fusion yield and dominant non-thermal fusion component because of the use of fundamental radio-frequency heating of a large minority in the scenario, which is calculated to have provided ∼10% to the total fusion power.

Published

2023

3. Impact of interaction between RF waves and fast NBI ions on the fusion performance in JET DTE2 campaign

Author

K.K. Kirov, C.D. Challis, E. De la Luna, J. Eriksson, D. Gallart, J. Garcia, M. Gorelenkova, J. Hobirk, P. Jacquet, A. Kappatou, Y.O. Kazakov, D. Keeling, D. King, E. Lerche, C. Maggi, J. Mailloux, P. Mantica, M. Mantsinen, M. Maslov, S. Menmuir, P. Siren, Z. Stancar, D. Van Eester, and JET Contributors

Subjects

RF waves, fast ions, DT plasma, JET, fusion performance, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

This work presents a study of the interaction between radio frequency (RF) waves used for ion cyclotron resonance heating and the fast deuterium (D) and tritium (T) neutral Beam injected (NBI) ions in DT plasma. The focus is on the effects of this interaction, also referred to as synergistic effects, on the fusion performance in the recent JET DTE2 campaign. Experimental data from dedicated pulses at 3.43 T/2.3 MA heated at (i) 51.4 MHz, giving the central minority H and n = 2 D, and at (ii) 32.2 MHz for the central minority ^3 He and n = 2 T. Resonances are analysed and conclusions are drawn and supported by modelling of the synergistic effects. Modelling with transport code TRANSP runs with and without the RF kick operator predict a moderate increase, of about 10%, in DT rates for the case of the RF wave—fast D NBI ion interactions at the n = 2 harmonic of ion cyclotron resonance, and a negligible impact due to synergistic interaction between fast T NBI ions and RF waves. JETTO modelling gives a 29% enhancement in fusion rates due to the interction between RF waves and fast D NBI ions, and an 18% enhancement in fast T NBI ions. Analysis of experimental neutron rates compared to TRANSP predictions without synergistic effects and magnetic proton recoil neutron spectrometer indicate an enhancement of approximately 25%–28% in fusion rates due to RF interaction with fast D ions, and an enhancement of approximately 5%–8% when RF waves and fast T NBI ions are interacting. The contributions of various heating and fast ion sources are assessed and discussed.

Published

2023

4. Modelling neutral beams in fusion devices: Beamlet-based model for fast particle simulations.

Author

Otto Asunta, Joonas Govenius, Robert Budny, M. Gorelenkova, G. Tardini, T. Kurki-Suonio, A. Salmi, and Seppo Sipilä

Published

2015

5. Validation of realistic Monte Carlo plasma gamma-ray source on JET discharges

Author

??ohar, A, Nocente, M, Kos, B, ??tancar, ?, Rebai, M, Rigamonti, D, Craciunescu, T, Gorelenkova, M, Kazakov, Y, Kiptily, V, Snoj, L, Tardocchi, M, Lengar, I, Contributors, J, A. ??ohar, M. Nocente, B. Kos, ??. ??tancar, M. Rebai, D. Rigamonti, T. Craciunescu, M. Gorelenkova, Ye. O. Kazakov, V. G. Kiptily, L. Snoj, M. Tardocchi, I. Lengar, JET Contributors, ??ohar, A, Nocente, M, Kos, B, ??tancar, ?, Rebai, M, Rigamonti, D, Craciunescu, T, Gorelenkova, M, Kazakov, Y, Kiptily, V, Snoj, L, Tardocchi, M, Lengar, I, Contributors, J, A. ??ohar, M. Nocente, B. Kos, ??. ??tancar, M. Rebai, D. Rigamonti, T. Craciunescu, M. Gorelenkova, Ye. O. Kazakov, V. G. Kiptily, L. Snoj, M. Tardocchi, I. Lengar, and JET Contributors

Abstract

A novel modelling methodology has been developed for the creation of a realistic plasma gamma-ray source for Monte Carlo transport simulations in the tokamak JET. The methodology couples the TRANSP code for plasma transport calculations with the MCNP Monte Carlo particle transport code, thus connecting plasma physics with gamma-ray transport. This paper presents the validation of the developed source methodology by comparing calculated gamma-ray spectra with measurements performed at JET. The validation focuses on gamma-ray spectra measured by the tangential gamma-ray spectrometer during two JET three ion RF scenario discharges, performed in the JET 2019 deuterium experimental campaign. For validation the calculated plasma gamma-ray spectrum was combined with the neutron induced prompt gamma-ray background, originating in the vacuum vessel, and scaled to absolute values calculating the total number of plasma gamma-ray and neutron emitting reactions. The comparison between calculated and measured gamma-ray spectra shows good agreement with the shape of the calculated gamma-ray spectra matching that of measurements for both studied discharges. Moreover, the calculated absolute values of the gamma-ray spectra were of the same order of magnitude at the position of the gamma-ray detector located at the end of a long line-of-sight in a biological shield. The comparison has validated the developed plasma gamma-ray source methodology for MCNP photon transport calculations at JET. The validation provides a basis for the developed plasma gamma-ray source to be used as a support for the development of future tokamaks such as DEMO.

Published

2022

6. Validation of realistic Monte Carlo plasma gamma-ray source on JET discharges

Author

A. Žohar, M. Nocente, B. Kos, Ž. Štancar, M. Rebai, D. Rigamonti, T. Craciunescu, M. Gorelenkova, Ye.O. Kazakov, V.G. Kiptily, L. Snoj, M. Tardocchi, I. Lengar, null JET Contributors, ohar, A, Nocente, M, Kos, B, tancar, ?, Rebai, M, Rigamonti, D, Craciunescu, T, Gorelenkova, M, Kazakov, Y, Kiptily, V, Snoj, L, Tardocchi, M, Lengar, I, and Contributors, J

Subjects

Nuclear and High Energy Physics, TRANSP, plasma gamma-rays, Physics::Plasma Physics, JET, Astrophysics::High Energy Astrophysical Phenomena, MCNP, plasma gamma-ray, Condensed Matter Physics, tokamak

Abstract

A novel modelling methodology has been developed for the creation of a realistic plasma gamma-ray source for Monte Carlo transport simulations in the tokamak JET. The methodology couples the TRANSP code for plasma transport calculations with the MCNP Monte Carlo particle transport code, thus connecting plasma physics with gamma-ray transport. This paper presents the validation of the developed source methodology by comparing calculated gamma-ray spectra with measurements performed at JET. The validation focuses on gamma-ray spectra measured by the tangential gamma-ray spectrometer during two JET three ion RF scenario discharges, performed in the JET 2019 deuterium experimental campaign. For validation the calculated plasma gamma-ray spectrum was combined with the neutron induced prompt gamma-ray background, originating in the vacuum vessel, and scaled to absolute values calculating the total number of plasma gamma-ray and neutron emitting reactions. The comparison between calculated and measured gamma-ray spectra shows good agreement with the shape of the calculated gamma-ray spectra matching that of measurements for both studied discharges. Moreover, the calculated absolute values of the gamma-ray spectra were of the same order of magnitude at the position of the gamma-ray detector located at the end of a long line-of-sight in a biological shield. The comparison has validated the developed plasma gamma-ray source methodology for MCNP photon transport calculations at JET. The validation provides a basis for the developed plasma gamma-ray source to be used as a support for the development of future tokamaks such as DEMO.

Published

2022

7. Alfvén eigenmode stability in a JET afterglow deuterium plasma and projections to deuterium–tritium plasmas

Author

A A Teplukhina, M Podestà, F M Poli, M Gorelenkova, P J Bonofiglo, C S Collins, R J Dumont, N C Hawkes, D L Keeling, M Sertoli, G Szepesi, A Thorman, and JET Contributors

Subjects

Nuclear Energy and Engineering, Condensed Matter Physics

Abstract

The performance of fusion devices relies strongly on the good confinement of energetic particles (EPs). Therefore, the investigation of EP transport by magnetohydrodynamic instabilities is one of the key aspects in the development of plasma scenarios. Alfvénic instabilities in particular can lead to significant losses of alpha particles that are essential for plasma self-heating. A so-called afterglow scheme has been developed to study the destabilization of Alfvén eigenmodes (AEs) by alpha particles and associated EP transport in the JET tokamak. In this work, the linear stability of AEs is discussed for the partial afterglow phase in a JET deuterium plasma discharge and for the full afterglow phase in a projected deuterium–tritium (DT) plasma. Thanks to recent upgrades in the tokamak transport code TRANSP, one can account for the contributions of different EP species to mode stability. Analysis of deuterium plasmas shows that AE growth rates are extremely sensitive to the energy and distribution of fast ions. An increase in fast ion energy can lead to more unstable AEs. In the afterglow phase of projected DT plasmas, it is EPs that mostly drive the AEs. However, the drive by alpha particles is comparable to that by beam ions and their contribution to the net growth rate might be hard to separate. According to the discussed projections, the destabilization of AEs might be ineffective because the background plasma damping significantly exceeds the EP drive. In this case, the development of an alternative plasma scenario that allows us to overcome such damping would be required in future experiments.

Published

2023

8. Extension of the energetic particle transport kick model in TRANSP to multiple fast ion species

Author

M. Podestà, M. Gorelenkova, A.A. Teplukhina, P.J. Bonofiglo, R. Dumont, D. Keeling, F.M. Poli, R.B. White, and null JET Contributors

Subjects

Nuclear and High Energy Physics, Condensed Matter Physics

Abstract

Alfvénic instabilities (AEs) are well known to cause enhanced transport of energetic particles (EPs) in fusion devices. Most studies until now have focused on characterizing and understanding AE stability in single-species plasmas heated by neutral beams (NB), where deuterium is typically used as both main plasma species and NB fuel. As the fusion community moves toward fusion reactors that target burning plasma conditions, such as ITER, the single-species picture breaks down. Burning plasmas, which will use a mix of deuterium and tritium (DT) as main fuel, also feature the presence of several supra-thermal fusion products such as alpha particles, protons, helium isotopes and high-energy tritium ions. This work presents the extension of the EP transport kick model implemented in the TRANSP time-dependent tokamak transport code to study the combined effect of multiple EP species on AE stability and, in turn, the response of different EP species to plasma instabilities in terms of their redistribution and losses. Further validation of the enhanced model is planned based on experimental results expected from the JET DT campaign scheduled for 2021, in preparation for ITER plasmas and beyond.

Published

2022

9. Validation of neutron emission and neutron energy spectrum calculations on a Mega Ampere Spherical Tokamak with directional relativistic spectrum simulator

Author

A. Sperduti, I. Klimek, M. Gorelenkova, Antti Snicker, Marco Cecconello, Sean Conroy, Uppsala University, Princeton Plasma Physics Laboratory, Department of Applied Physics, Aalto-yliopisto, and Aalto University

Subjects

Physics, Thesaurus (information retrieval), Mega Ampere Spherical Tokamak, Neutron emission, Astrophysics::High Energy Astrophysical Phenomena, Spectrum (functional analysis), Condensed Matter Physics, Neutron energy spectrum, 01 natural sciences, 7. Clean energy, 010305 fluids & plasmas, Computational physics, Nuclear Energy and Engineering, Physics::Plasma Physics, 0103 physical sciences, 010306 general physics

Abstract

openaire: EC/H2020/633053/EU//EUROfusion The recently developed directional relativistic spectrum simulator (DRESS) code has been validated for the first time against numerical calculations and experimental measurements performed on the Mega Ampere Spherical Tokamak . In this validation, the neutron emissivities and rates computed by DRESS are benchmarked against TRANSP/NUBEAM predictions while the neutron energy spectra provided by DRESS taking as input TRANSP/NUBEAM and ASCOT/BBNBI in Gyro-Orbit mode fast ion distributions are validated against proton pulse height spectra measured by the neutron flux monitor. Excellent agreement was found between DRESS and TRANSP/NUBEAM predictions of local and total neutron emission.

Published

2021

10. Experimental validation of an integrated modelling approach to neutron emission studies at JET

Author

Gabor Szepesi, Ye. O. Kazakov, H. Weisen, Sean Conroy, Teddy Craciunescu, P. Sirén, Vladimir Radulović, L. Garzotti, Andrej Žohar, Jet Contributors, Luka Snoj, M. Dreval, Massimo Nocente, Jacob Eriksson, M. Gorelenkova, E. Militello-Asp, Žiga Štancar, Y. Baranov, Vasily Kiptily, Z. Ghani, K. Kirov, Stancar, Z, Ghani, Z, Eriksson, J, Zohar, A, Conroy, S, Kazakov, Y, Craciunescu, T, Kirov, K, Nocente, M, Garzotti, L, Radulovic, V, Siren, P, Kiptily, V, Baranov, Y, Szepesi, G, Dreval, M, Gorelenkova, M, Weisen, H, Militello-Asp, E, and Snoj, L

Subjects

neutron diagnostics, Nuclear and High Energy Physics, TRANSP, Neutron emission, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, neutron activation, 01 natural sciences, 010305 fluids & plasmas, Nuclear physics, Physics::Plasma Physics, generation, 0103 physical sciences, diagnostics, fast ion, fast ions, 010306 general physics, Nuclear Experiment, tokamak, Physics, Jet (fluid), integrated modeling, Experimental validation, plasma neutron source, Condensed Matter Physics, calibration, plasmas, collaboration, JET, neutron diagnostic, integrated modelling, energy

Abstract

An integrated modelling methodology for the calculation of realistic plasma neutron sources for the JET tokamak has been developed. The computational chain comprises TRANSP plasma transport and DRESS neutron spectrum calculations, and their coupling to the MCNP neutron transport code, bridging plasma physics and neutronics. In the paper we apply the developed methodology to the analysis of neutron emission properties of deuterium and helium plasmas at JET, and validate individual modelling steps against neutron diagnostic measurements. Two types of JET discharges are modelled-baseline-like and three-ion radio-frequency scenarios-due to their diversity in plasma heating, characteristics of the induced fast ion population, and the imprint of these on neutron emission properties. The neutron emission modelling results are quantitatively compared to the total neutron yield from fission chambers, neutron emissivity profiles from the neutron camera, neutron spectra from the time-of-flight spectrometer, and neutron activation measurements. The agreement between measured and calculated quantities is found to be satisfactory for all four diagnostic systems within the estimated experimental and computational uncertainties. Additionally, the effect of neutrons not originating from the dominating D(D, n)He-3 reactions is studied through modelling of triton burnup DT neutrons, and, in mixed D-He-3 plasmas, neutrons produced in the Be-9(D, n gamma)B-10 reaction on impurities. It is found that these reactions can contribute up to several percent to the total neutron yield and dominate the neutron activation of samples. The effect of MeV-range fast ions on the neutron activation of In-115 and Al-27 samples is measured and computationally validated.

Published

2021

11. Fast ion transport by sawtooth instability in the presence of ICRF-NBI synergy in JET plasmas

Author

Mario Podesta, M. Gorelenkova, Massimo Nocente, F.M. Poli, Jet Contributors, A. A. Teplukhina, Žiga Štancar, Gabor Szepesi, P.J. Bonofiglo, J. Ongena, Ye. O. Kazakov, Teplukhina, A, Podesta, M, Poli, F, Szepesi, G, Kazakov, Y, Bonofiglo, P, Gorelenkova, M, Nocente, M, Ongena, J, and Stancar, Z

Subjects

Physics, Nuclear and High Energy Physics, Jet (fluid), TRANSP, sawtooth instability, fast ion transport, Plasma, Condensed Matter Physics, ORBIT, three-ion ICRF heating, Nuclear physics, Physics::Plasma Physics, Sawtooth instability, integrated modelling, ICRF-NBI synergy, Ion transporter

Abstract

JET experiments have shown that the three-ion scenarios using waves in the ion cyclotron range of frequencies (ICRF) is an efficient way to build fast ion population through beam ion acceleration by radio frequency (RF) waves. Such a heating scheme is applied to plasmas with at least two thermal ion species. Analysis of mixed discharges with complex heating schemes requires a workflow that allows to model thermal and fast ion transport consistently. This paper is dedicated to modelling of a mixed plasma discharge with significant fraction of fast ions and contributes to development of fast ion transport models. For interpretive analysis with the TRANSP code a JET hydrogen-deuterium plasma discharge with neutral beam injection (NBI) and ICRF heating has been chosen. The task is complicated by NBI-ICRF synergy and plasma magnetohydrodynamic activity, like sawtooth crashes. D beam ions accelerated by RF waves form a high energy tail in fast ion distribution. Significant difference between the neutron rate computed by TRANSP and measured one is observed if the same diffusivity for electrons and ions is assumed. Sensitivity studies show that uncertainties in input plasma parameters and thermal ion transport models are crucial for modelling mixed plasma discharges and increased D transport is required to reach the plasma composition consistent with diagnostic measurements at the plasma edge. Fast ion redistribution by a sawtooth instability is characterised by non-resonant transport due to reconnection of magnetic field lines and resonant transport caused by resonance interaction between the instability and fast ions. With ORBIT simulations it has been shown that resonant interaction strongly affects fast ions of high energies, like beam ions accelerated by RF waves and fusion products. For the considered case, fast ion profiles simulated by ORBIT remain peaked after the sawtooth crashes.

Published

2021

12. Reduced energetic particle transport models enable comprehensive time-dependent tokamak simulations

Author

Cami Collins, William Heidbrink, L. Bardoczi, D. Liu, Roscoe White, Francesca Poli, G. J. Kramer, Mario Podesta, M. Gorelenkova, Nikolai Gorelenkov, Vinicius Duarte, E.D. Fredrickson, D. Kim, and M. A. Van Zeeland

Subjects

Physics, Nuclear and High Energy Physics, Tokamak, law, Nuclear engineering, Condensed Matter Physics, Particle transport, law.invention

Published

2019

13. Overview of recent physics results from MAST

Author

A. Kirk, J. Horacek, C. D. Challis, I. Klimek, W. A. Peebles, K. Imada, W. A. Gracias, H. R. Wilson, A. W. Morris, L. Piron, K Tani, M. Wischmeier, Sean Conroy, D. A. Ryan, M. O’Brien, F. Arese Lucini, Fabio Riva, Ryota Imazawa, Sandra C. Chapman, Anders Nielsen, P. Cahyna, Nick Walkden, Michael Barnes, I. Fitzgerald, C. Gurl, G. Fishpool, A. Patel, Takuma Yamada, M. Cecconello, M. Turnyanskiy, Ben F. McMillan, A. R. Field, G. Cunningham, Y. Liu, T.R. Barrett, F. J. Casson, Michael F. J. Fox, M. Cox, G. Naylor, A.J. Thornton, Matthew Carr, Nicolas Fedorczak, R. Scannell, L. Pangione, L. Garzotti, N. C. Hawkes, Hiroshi Tanabe, T. Farley, Yasushi Ono, M. Evans, Gen Motojima, Daniel Dunai, T. O'Gorman, S. Saarelma, William Dorland, H. F. Meyer, G. McArdle, B. Huang, E. Havlickova, T. Watanabe, Michiaki Inomoto, R. O. Dendy, Paolo Ricci, Edmund Highcock, F. van Wyk, H. Leggate, Matthias Komm, Jens Madsen, Alexander Schekochihin, S. A. Silburn, I. T. Chapman, S.M. Kaye, Hajime Tanaka, Jeppe Olsen, F. Militello, S. D. Pinches, R. V. Perez, D. Harting, K. G. McClements, Jarrod Leddy, C. M. Roach, Roddy G. L. Vann, Luke Easy, Walter Guttenfelder, Patrick Tamain, Benjamin Daniel Dudson, M. G. O'Mullane, John Omotani, W. A. Cooper, B. Lloyd, Felix I. Parra, K. J. Gibson, EUROfusion Mst Team, S. Cardnell, N. J. Conway, O. M. Jones, W. Lai, J. Young, S. S. Henderson, Brendan M. Crowley, Romualdo Martín, Neal Crocker, A. Meakins, A. V. Danilov, Ray M. Sharples, D. L. Keeling, M. Gorelenkova, J. Simpson, J. Hollocombe, J. Adamek, Bogdan Hnat, N. Ben Ayed, L Kogan, Matthew Reinke, M. Valovic, J. R. Harrison, Bruce Lipschultz, Vladimir Shevchenko, Clive Michael, J. Storrs, M. Romanelli, M. Price, S. E. Sharapov, John Howard, J. Mailloux, N. Thomas-Davies, D. Muir, Stanislas Pamela, David Dickinson, James W. Bradley, M. Kocan, J. Chorley, Philippa Browning, H. P. Summers, Yuichi Takase, Vyacheslav S. Lukin, G. P. Maddison, J. Milnes, Keii Gi, L. Appel, Adam Stanier, Daniel Thomas, S. Allan, Ivan Lupelli, Young-chul Ghim, D. F. Howell, J. C. Hillesheim, S.W. Lisgo, A. N. Saveliev, David Taylor, W. Boeglin, Kazutake Kadowaki, J. Brunner, C. Ham, R. J. Akers, D. S. Darrow, B. Lomanowski, T. C. Hender, S. Elmore, Mast Team, Simon Freethy, S. Zoletnik, Kouji Shinohara, MAST Team, and EUROfusion MST1 Team

Subjects

Physics, Nuclear and High Energy Physics, Toroid, Turbulence, Divertor, FOS: Physical sciences, Electron, Plasma, Condensed Matter Physics, 7. Clean energy, 01 natural sciences, Resonant magnetic perturbations, Physics - Plasma Physics, 010305 fluids & plasmas, Computational physics, Plasma Physics (physics.plasm-ph), Pedestal, Physics::Plasma Physics, 0103 physical sciences, Electron temperature, 010306 general physics

Abstract

New results from MAST are presented that focus on validating models in order to extrapolate to future devices. Measurements during start-up experiments have shown how the bulk ion temperature rise scales with the square of the reconnecting field. During the current ramp up models are not able to correctly predict the current diffusion. Experiments have been performed looking at edge and core turbulence. At the edge detailed studies have revealed how filament characteristic are responsible for determining the near and far SOL density profiles. In the core the intrinsic rotation and electron scale turbulence have been measured. The role that the fast ion gradient has on redistributing fast ions through fishbone modes has led to a redesign of the neutral beam injector on MAST Upgrade. In H-mode the turbulence at the pedestal top has been shown to be consistent with being due to electron temperature gradient modes. A reconnection process appears to occur during ELMs and the number of filaments released determines the power profile at the divertor. Resonant magnetic perturbations can mitigate ELMs provided the edge peeling response is maximised and the core kink response minimised. The mitigation of intrinsic error fields with toroidal mode number n>1 has been shown to be important for plasma performance., 34 pages, 10 figures. This is an author-created, un-copyedited version of an article submitted for publication in Nuclear Fusion. IoP Publishing Ltd is not responsible for any errors or omissions in this version of the manuscript or any version derived from it

Published

2016

14. Destabilization of counter-propagating Alfvénic instabilities by tangential, co-current neutral beam injection

Author

E.D. Fredrickson, Mario Podesta, and M. Gorelenkova

Subjects

Physics, Nuclear and High Energy Physics, 0103 physical sciences, Current (fluid), Atomic physics, 010306 general physics, Condensed Matter Physics, 01 natural sciences, Neutral beam injection, 010305 fluids & plasmas

Published

2018

15. Modelling neutral beams in fusion devices: Beamlet-based model for fast particle simulations

Author

Anna Salmi, M. Gorelenkova, Seppo Sipilä, Joonas Govenius, Taina Kurki-Suonio, G. Tardini, Otto Asunta, Robert Budny, ASDEX Upgrade Team, Max Planck Institute for Plasma Physics, Max Planck Society, and JET EFDA Contributors

Subjects

Physics, Tokamak, General Physics and Astronomy, Plasma, 01 natural sciences, Neutral beam injection, 010305 fluids & plasmas, Pencil (optics), Computational physics, law.invention, Nuclear physics, ASDEX Upgrade, Hardware and Architecture, law, Ionization, 0103 physical sciences, Test particle, 010306 general physics, Beam (structure)

Abstract

Neutral beam injection (NBI) will be one of the main sources of heating and non-inductive current drive in ITER. Due to high level of injected power the beam induced heat loads present a potential threat to the integrity of the first wall of the device, particularly in the presence of non-axisymmetric perturbations of the magnetic field. Neutral beam injection can also destabilize Alfven eigenmodes and energetic particle modes, and act as a source of plasma rotation. Therefore, reliable and accurate simulation of NBI is important for making predictions for ITER, as well as for any other current or future fusion device. This paper introduces a new beamlet-based neutral beam ionization model called BBNBI. It takes into account the fine structure of the injector, follows the injected neutrals until ionization, and generates a source ensemble of ionized NBI test particles for slowing down calculations. BBNBI can be used as a stand-alone model but together with the particle following code ASCOT it forms a complete and sophisticated tool for simulating neutral beam injection. The test particle ensembles from BBNBI are found to agree well with those produced by PENCIL for JET, and those produced by NUBEAM both for JET and ASDEX Upgrade plasmas. The first comprehensive comparisons of beam slowing down profiles of interest from BBNBI + ASCOT with results from PENCIL and NUBEAM/TRANSP, for both JET and AUG, are presented. It is shown that, for an axisymmetric plasma, BBNBI + ASCOT and NUBEAM agree remarkably well. Together with earlier 3D studies, these results further validate using BBNBI + ASCOT also for studying phenomena that require particle following in a truly three-dimensional geometry.

Published

2015

16. An overview of recent physics results from NSTX

Author

C. K. Phillips, Vlad Soukhanovskii, Bruce E. Koel, W. X. Wang, Tobin Munsat, D. S. Darrow, Tyler Abrams, B. Stratton, David N. Ruzic, M. Lucia, James R. Wilson, Kimin Kim, Mario Podesta, W. A. Peebles, R. Maingi, R. Bilato, T.K. Gray, Stanley Kaye, Ahmed Diallo, Dylan Brennan, R.E. Bell, Richard Majeski, Stephane Ethier, Valeryi Sizyuk, B.P. LeBlanc, Angela M. Capece, Amitava Bhattacharjee, J.A. Boedo, D. J. Battaglia, L.L. Lao, Robert Kaita, Nikolai Gorelenkov, E. B. Hooper, P. B. Snyder, S.A. Sabbagh, Brian Nelson, Clarence W. Rowley, J.M. Bialek, S.P. Gerhardt, Dennis Boyle, X. Yuan, Eugenio Schuster, F. Bedoya, W. Guttenfelder, A. H. Glasser, Lee A. Berry, G. J. Kramer, Todd Evans, Leonid E. Zakharov, L. F. Delgado-Aparicio, George McKee, D.P. Stotler, I.R. Goumiri, S. Kubota, D. A. Russell, Y. Sechrest, Neville C. Luhmann, F. Ebrahimi, E. F. Jaeger, Stephen Jardin, Ker-Chung Shaing, David R. Smith, W. M. Solomon, M.L. Walker, T.H. Osborne, Fred Levinton, Michael Jaworski, Zhehui Wang, E.T. Meier, Seung-Hoe Ku, J.R. Ferron, Thomas Jarboe, Guoyong Fu, Allen H. Boozer, Roger Raman, P.M. Ryan, David Gates, Choong-Seock Chang, Egemen Kolemen, Filippo Scotti, Jinseop Park, D.A. D'Ippolito, William Heidbrink, R. J. Lahaye, R. Barchfeld, Calvin Domier, J.H. Nichols, D. W. Liu, R.J. Maqueda, Rory Perkins, J. Breslau, Brian D. Wirth, Kevin Tritz, Roscoe White, Yang Ren, M. Gorelenkova, D.K. Mansfield, Jean Paul Allain, R. J. Buttery, John Canik, R.J. Fonck, M. Ono, E.D. Fredrickson, R. Andre, Alessandro Bortolon, J. Lore, Francesca Poli, Michael Finkenthal, S. S. Medley, Edward A. Startsev, D. L. Green, Joon-Wook Ahn, G. Taylor, J.P. Roszell, Chase N. Taylor, C.E. Kessel, Nicola Bertelli, J. Hosea, Ahmed Hassanein, Howard Yuh, Yoshiki Hirooka, J.R. Myra, C.H. Skinner, Christopher Muscatello, Neal Crocker, D.A. Humphreys, Nathaniel Ferraro, Tatyana Sizyuk, Elena Belova, P.T. Bonoli, W. Davis, John Berkery, M. D. Boyer, Stewart Zweben, Dan Stutman, Jonathan Menard, R. W. Harvey, Jeffrey N. Brooks, John Wright, D. Mueller, Peter Beiersdorfer, C. Sovenic, and Daniel Andruczyk

Subjects

Physics, Nuclear and High Energy Physics, Toroid, Tokamak, Plasma, Collisionality, Condensed Matter Physics, Instability, Computational physics, law.invention, Heat flux, Physics::Plasma Physics, law, Electromagnetic shielding, Nuclear fusion, Atomic physics

Abstract

The National Spherical Torus Experiment (NSTX) is currently being upgraded to operate at twice the toroidal field and plasma current (up to 1 T and 2 MA), with a second, more tangentially aimed neutral beam (NB) for current and rotation control, allowing for pulse lengths up to 5 s. Recent NSTX physics analyses have addressed topics that will allow NSTX-Upgrade to achieve the research goals critical to a Fusion Nuclear Science Facility. These include producing stable, 100% non-inductive operation in high-performance plasmas, assessing plasma–material interface (PMI) solutions to handle the high heat loads expected in the next-step devices and exploring the unique spherical torus (ST) parameter regimes to advance predictive capability. Non-inductive operation and current profile control in NSTX-U will be facilitated by co-axial helicity injection (CHI) as well as radio frequency (RF) and NB heating. CHI studies using NIMROD indicate that the reconnection process is consistent with the 2D Sweet–Parker theory. Full-wave AORSA simulations show that RF power losses in the scrape-off layer (SOL) increase significantly for both NSTX and NSTX-U when the launched waves propagate in the SOL. Toroidal Alfven eigenmode avalanches and higher frequency Alfven eigenmodes can affect NB-driven current through energy loss and redistribution of fast ions. The inclusion of rotation and kinetic resonances, which depend on collisionality, is necessary for predicting experimental stability thresholds of fast growing ideal wall and resistive wall modes. Neutral beams and neoclassical toroidal viscosity generated from applied 3D fields can be used as actuators to produce rotation profiles optimized for global stability. DEGAS-2 has been used to study the dependence of gas penetration on SOL temperatures and densities for the MGI system being implemented on the Upgrade for disruption mitigation. PMI studies have focused on the effect of ELMs and 3D fields on plasma detachment and heat flux handling. Simulations indicate that snowflake and impurity seeded radiative divertors are candidates for heat flux mitigation in NSTX-U. Studies of lithium evaporation on graphite surfaces indicate that lithium increases oxygen surface concentrations on graphite, and deuterium–oxygen affinity, which increases deuterium pumping and reduces recycling. In situ and test-stand experiments of lithiated graphite and molybdenum indicate temperature-enhanced sputtering, although that test-stand studies also show the potential for heat flux reduction through lithium vapour shielding. Non-linear gyro kinetic simulations have indicated that ion transport can be enhanced by a shear-flow instability, and that non-local effects are necessary to explain the observed rapid changes in plasma turbulence. Predictive simulations have shown agreement between a microtearing-based reduced transport model and the measured electron temperatures in a microtearing unstable regime. Two Alfven eigenmode-driven fast ion transport models have been developed and successfully benchmarked against NSTX data. Upgrade construction is moving on schedule with initial physics research operation of NSTX-U planned for mid-2015.

Published

2015

17. Computation of Alfvèn eigenmode stability and saturation through a reduced fast ion transport model in the TRANSP tokamak transport code

Author

N. N. Gorelenkov, Mario Podesta, Roscoe White, and M. Gorelenkova

Subjects

Physics, education.field_of_study, Tokamak, Computation, Population, Plasma, Condensed Matter Physics, 01 natural sciences, Neutral beam injection, 010305 fluids & plasmas, Computational physics, law.invention, Ion, Amplitude, Nuclear Energy and Engineering, Physics::Plasma Physics, Normal mode, law, 0103 physical sciences, Atomic physics, 010306 general physics, education

Abstract

Alfvenic instabilities (AEs) are well known as a potential cause of enhanced fast ion transport in fusion devices. Given a specific plasma scenario, quantitative predictions of (i) expected unstable AE spectrum and (ii) resulting fast ion transport are required to prevent or mitigate the AE-induced degradation in fusion performance. Reduced models are becoming an attractive tool to analyze existing scenarios as well as for scenario prediction in time-dependent simulations. In this work, a neutral beam heated NSTX discharge is used as reference to illustrate the potential of a reduced fast ion transport model, known as kick model, that has been recently implemented for interpretive and predictive analysis within the framework of the time-dependent tokamak transport code TRANSP. Predictive capabilities for AE stability and saturation amplitude are first assessed, based on given thermal plasma profiles only. Predictions are then compared to experimental results, and the interpretive capabilities of the model further discussed. Overall, the reduced model captures the main properties of the instabilities and associated effects on the fast ion population. Additional information from the actual experiment enables further tuning of the model's parameters to achieve a close match with measurements.

Published

2017

18. Full-wave simulations of ICRF heating regimes in toroidal plasma with non-Maxwellian distribution functions

Author

C. K. Phillips, Jungpyo Lee, Nicola Bertelli, E. F. Jaeger, D. L. Green, John Wright, E. J. Valeo, Mario Podesta, and M. Gorelenkova

Subjects

Physics, Nuclear and High Energy Physics, Toroid, Tokamak, Wave propagation, Plasma, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, law.invention, Ion, Computational physics, Distribution function, Physics::Plasma Physics, law, Physics::Space Physics, 0103 physical sciences, 010306 general physics, Absorption (electromagnetic radiation), Beam (structure)

Abstract

At the power levels required for significant heating and current drive in magnetically-confined toroidal plasma, modification of the particle distribution function from a Maxwellian shape is likely (Stix 1975 Nucl. Fusion 15 737), with consequent changes in wave propagation and in the location and amount of absorption. In order to study these effects computationally, both the finite-Larmor-radius and the high-harmonic fast wave (HHFW), versions of the full-wave, hot-plasma toroidal simulation code TORIC (Brambilla 1999 Plasma Phys. Control. Fusion 41 1 and Brambilla 2002 Plasma Phys. Control. Fusion 44 2423), have been extended to allow the prescription of arbitrary velocity distributions of the form . For hydrogen (H) minority heating of a deuterium (D) plasma with anisotropic Maxwellian H distributions, the fractional H absorption varies significantly with changes in parallel temperature but is essentially independent of perpendicular temperature. On the other hand, for HHFW regime with anisotropic Maxwellian fast ion distribution, the fractional beam ion absorption varies mainly with changes in the perpendicular temperature. The evaluation of the wave-field and power absorption, through the full wave solver, with the ion distribution function provided by either a Monte-Carlo particle and Fokker–Planck codes is also examined for Alcator C-Mod and NSTX plasmas. Non-Maxwellian effects generally tend to increase the absorption with respect to the equivalent Maxwellian distribution.

Published

2017

19. Effects of energetic particle phase space modifications by instabilities on integrated modeling

Author

M. Gorelenkova, Mario Podesta, Roscoe White, N. N. Gorelenkov, and E.D. Fredrickson

Subjects

Physics, Nuclear and High Energy Physics, education.field_of_study, Tokamak, Momentum transfer, Population, Mechanics, Plasma, Condensed Matter Physics, 01 natural sciences, Neutral beam injection, 010305 fluids & plasmas, law.invention, Distribution function, Physics::Plasma Physics, law, Phase space, 0103 physical sciences, Nuclear fusion, Atomic physics, 010306 general physics, education

Abstract

Tokamak plasmas can feature a large population of energetic particles (EP) from neutral beam injection or fusion reactions. In turn, energetic particles can drive instabilities, which affect the driving EP population leading to a distortion of the original EP distribution function and of quantities that depend on it. The latter include, for example, neutral beam (NB) current drive and plasma heating through EP thermalization. Those effects must be taken into account to enable reliable and quantitative simulations of discharges for present devices as well as predictions for future burning plasmas. Reduced models for EP transport are emerging as an effective tool for long time-scale integrated simulations of tokamak plasmas, possibly including the effects of instabilities on EP dynamics. Available models differ in how EP distribution properties are modified by instabilities, e.g. in terms of gradients in real or phase space. It is therefore crucial to assess to what extent different assumptions in the transport models affect predicted quantities such as EP profile, energy distribution, NB driven current and energy/momentum transfer to the thermal populations. A newly developed kick model, which includes modifications of the EP distribution by instabilities in both real and velocity space, is used in this work to investigate these issues. Coupled to TRANSP simulations, the kick model is used to analyze NB-heated NSTX and DIII-D discharges featuring unstable Alfvén eigenmodes (AEs). Results show that instabilities can strongly affect the EP distribution function, and modifications propagate to macroscopic quantities such as NB-driven current profile and NB power transferred to the thermal plasma species. Those important aspects are only qualitatively captured by simpler fast ion transport models that are based on radial diffusion of energetic ions only.

Published

2016

20. Phase space effects on fast ion distribution function modeling in tokamaks

Author

Mario Podesta, E.D. Fredrickson, M. Gorelenkova, N. N. Gorelenkov, and Roscoe White

Subjects

Physics, Plasma, Condensed Matter Physics, Space (mathematics), 01 natural sciences, Stability (probability), 010305 fluids & plasmas, Distribution function, Phase space, 0103 physical sciences, Perturbation theory (quantum mechanics), Statistical physics, Magnetohydrodynamics, 010306 general physics, Transport phenomena

Abstract

Integrated simulations of tokamak discharges typically rely on classical physics to model energetic particle (EP) dynamics. However, there are numerous cases in which energetic particles can suffer additional transport that is not classical in nature. Examples include transport by applied 3D magnetic perturbations and, more notably, by plasma instabilities. Focusing on the effects of instabilities,ad-hocmodels can empirically reproduce increased transport, but the choice of transport coefficients is usually somehow arbitrary. New approaches based on physics-based reduced models are being developed to address those issues in a simplified way, while retaining a more correct treatment of resonant wave-particle interactions. The kick model implemented in the tokamaktransport code TRANSP is an example of such reduced models. It includes modifications of the EP distribution by instabilities in real and velocity space, retaining correlations between transport in energy and space typical of resonant EP transport. The relevance of EP phase space modifications by instabilities is first discussed in terms of predicted fast ion distribution. Results are compared with those from a simple, ad-hoc diffusive model. It is then shown that the phase-space resolved model can also provide additional insight into important issues such as internal consistency of the simulations and mode stability through the analysis of the power exchanged between energetic particles and the instabilities.

Published

2016

21. Implementation of a 3D halo neutral model in the TRANSP code and application to projected NSTX-U plasmas

Author

William Heidbrink, M. Gorelenkova, Luke Stagner, S. S. Medley, and D. Liu

Subjects

Physics, Monte Carlo method, Torus, Astrophysics::Cosmology and Extragalactic Astrophysics, Plasma, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Nuclear physics, Nuclear Energy and Engineering, Ionization, 0103 physical sciences, Halo, 010306 general physics, Neutral particle, Event (particle physics), Astrophysics::Galaxy Astrophysics, Beam (structure)

Abstract

A 3D halo neutral code developed at the Princeton Plasma Physics Laboratory and implemented for analysis using the TRANSP code is applied to projected National Spherical Torus eXperiment-Upgrade (NSTX-U plasmas). The legacy TRANSP code did not handle halo neutrals properly since they were distributed over the plasma volume rather than remaining in the vicinity of the neutral beam footprint as is actually the case. The 3D halo neutral code uses a 'beam-in-a-box' model that encompasses both injected beam neutrals and resulting halo neutrals. Upon deposition by charge exchange, a subset of the full, one-half and one-third beam energy components produce first generation halo neutrals that are tracked through successive generations until an ionization event occurs or the descendant halos exit the box. The 3D halo neutral model and neutral particle analyzer (NPA) simulator in the TRANSP code have been benchmarked with the Fast-Ion D-Alpha simulation (FIDAsim) code, which provides Monte Carlo simulations of beam neutral injection, attenuation, halo generation, halo spatial diffusion, and photoemission processes. When using the same atomic physics database, TRANSP and FIDAsim simulations achieve excellent agreement on the spatial profile and magnitude of beam and halo neutral densities and the NPA energy spectrum. The simulations show that the halo neutral density can be comparable to the beam neutral density. These halo neutrals can double the NPA flux, but they have minor effects on the NPA energy spectrum shape. The TRANSP and FIDAsim simulations also suggest that the magnitudes of beam and halo neutral densities are relatively sensitive to the choice of the atomic physics databases.

Published

2016

22. Effects of MHD instabilities on neutral beam current drive

Author

D. S. Darrow, E.D. Fredrickson, Stefan Gerhardt, Roscoe White, Mario Podesta, and M. Gorelenkova

Subjects

Physics, Nuclear and High Energy Physics, Tokamak, Plasma, Fusion power, Condensed Matter Physics, Neutral beam injection, Computational physics, law.invention, law, Nuclear fusion, Magnetohydrodynamics, Atomic physics, Current density, Beam (structure)

Abstract

Neutral beam injection (NBI) is one of the primary tools foreseen for heating, current drive (CD) and q-profile control in future fusion reactors such as ITER and a Fusion Nuclear Science Facility. However, fast ions from NBI may also provide the drive for energetic particle-driven instabilities (e.g. Alfvenic modes (AEs)), which in turn redistribute fast ions in both space and energy, thus hampering the control capabilities and overall efficiency of NB-driven current. Based on experiments on the NSTX tokamak (M. Ono et al 2000 Nucl. Fusion 40 557), the effects of AEs and other low-frequency magneto-hydrodynamic instabilities on NB-CD efficiency are investigated. A new fast ion transport model, which accounts for particle transport in phase space as required for resonant AE perturbations, is utilized to obtain consistent simulations of NB-CD through the tokamak transport code TRANSP. It is found that instabilities do indeed reduce the NB-driven current density over most of the plasma radius by up to ~50%. Moreover, the details of the current profile evolution are sensitive to the specific model used to mimic the interaction between NB ions and instabilities. Implications for fast ion transport modeling in integrated tokamak simulations are briefly discussed.

Published

2015

23. Reduced energetic particle transport models enable comprehensive time-dependent tokamak simulations.

Author

M. Podestà, L. Bardóczi, C.S. Collins, N.N. Gorelenkov, W.W. Heidbrink, V.N. Duarte, G.J. Kramer, E.D. Fredrickson, M. Gorelenkova, D. Kim, D. Liu, F.M. Poli, M.A. Van Zeeland, and R.B. White

Subjects

PLASMA beam injection heating, PLASMA instabilities, TRANSPORT theory, NEUTRAL beams, FAST ions, PARTICLES (Nuclear physics), PHASE space

Abstract

Time-dependent integrated simulations through codes such as TRANSP are becoming an indispensable tool for the interpretation of existing experiments and predictions of optimized scenarios. For many practical cases, quantitative simulations need to include the effect of plasma instabilities on the evolution of a tokamak discharge. An example is the degradation in energetic particle (EP) confinement induced by instabilities, which in turn affects important source terms for heating, non-inductive current, and momentum in a simulation. The reduced-physics kick model provides phase-space resolved transport probability matrices to TRANSP that are used to account for enhanced EP transport by instabilities in addition to neoclassical transport. The model has recovered the measured Alfvén eigenmode (AE) spectrum on NSTX, NSTX-U and DIII-D, and has reproduced details of phase-space resolved fast ion diagnostic data measured on DIII-D for EP-driven modes and tearing modes. In general, the kick model has proven the potential of phase-space resolved EP simulations to unravel details of EP transport for detailed theory/experiment comparison and for scenario planning based on optimization of neutral beam injection parameters. In this work, the extension of the kick model to low-frequency instabilities such as tearing modes and fishbones, in addition to AEs, is assessed. The goal is to enable TRANSP simulations that retain the main effects of multiple types of instabilities through a common framework. Results from the NSTX/NSTX-U and DIII-D tokamaks show that the extension to multi-mode scenarios can expand the range of applicability of the model for more reliable, quantitative integrated simulations. [ABSTRACT FROM AUTHOR]

Published

2019

24. Destabilization of counter-propagating Alfvénic instabilities by tangential, co-current neutral beam injection.

Author

M. Podestà, E.D. Fredrickson, and M. Gorelenkova

Subjects

PLASMA beam injection heating, CYCLOTRON resonance, FAST ions, STELLARATORS, NEUTRAL beams

Abstract

Injection of high-energy neutrals is a common tool to heat the plasma and drive current non-inductively in fusion devices. Once neutrals ionize, the resulting energetic particles can drive instabilities that are detrimental for the performance and the predictability of plasma discharges. A broad deposition profile of neutrals from neutral beam injection, e.g. by aiming the beam tangentially on the outboard midplane (i.e. off-axis), is often assumed to limit those undesired effects by reducing the radial gradient of the EP density, thus reducing the drive for instabilities. However, this work presents new evidence that tangential neutral beam injection, including off-axis injection near the plasma mid-radius, can also lead to undesired effects such as the destabilization of Alfvénic instabilities. Time-dependent analysis with the TRANSP code indicates that instabilities are driven by a combination of radial and energy gradients in the distribution function of the energetic particles. The mechanisms for wave-particle interaction revealed by the energetic particle phase space resolved analysis are the basis to identify strategies to mitigate or suppress the observed instabilities. [ABSTRACT FROM AUTHOR]

Published

2018

25. Computation of Alfvèn eigenmode stability and saturation through a reduced fast ion transport model in the TRANSP tokamak transport code.

Author

M Podestà, M Gorelenkova, N N Gorelenkov, and R B White

Subjects

*PLASMA beam injection heating, *SOLAR energetic particles, *ENERGY transfer, *TOKAMAKS, *PLASMA Alfven waves

Abstract

Alfvénic instabilities (AEs) are well known as a potential cause of enhanced fast ion transport in fusion devices. Given a specific plasma scenario, quantitative predictions of (i) expected unstable AE spectrum and (ii) resulting fast ion transport are required to prevent or mitigate the AE-induced degradation in fusion performance. Reduced models are becoming an attractive tool to analyze existing scenarios as well as for scenario prediction in time-dependent simulations. In this work, a neutral beam heated NSTX discharge is used as reference to illustrate the potential of a reduced fast ion transport model, known as kick model, that has been recently implemented for interpretive and predictive analysis within the framework of the time-dependent tokamak transport code TRANSP. Predictive capabilities for AE stability and saturation amplitude are first assessed, based on given thermal plasma profiles only. Predictions are then compared to experimental results, and the interpretive capabilities of the model further discussed. Overall, the reduced model captures the main properties of the instabilities and associated effects on the fast ion population. Additional information from the actual experiment enables further tuning of the model’s parameters to achieve a close match with measurements. [ABSTRACT FROM AUTHOR]

Published

2017

26. Full-wave simulations of ICRF heating regimes in toroidal plasma with non-Maxwellian distribution functions.

Author

N. Bertelli, E.J. Valeo, D.L. Green, M. Gorelenkova, C.K. Phillips, M. Podestà, J.P. Lee, J.C. Wright, and E.F. Jaeger

Subjects

TOROIDAL plasma, DISTRIBUTION (Probability theory), PARTICLE dynamics analysis, ANISOTROPY, PLASMA physics

Abstract

At the power levels required for significant heating and current drive in magnetically-confined toroidal plasma, modification of the particle distribution function from a Maxwellian shape is likely (Stix 1975 Nucl. Fusion15 737), with consequent changes in wave propagation and in the location and amount of absorption. In order to study these effects computationally, both the finite-Larmor-radius and the high-harmonic fast wave (HHFW), versions of the full-wave, hot-plasma toroidal simulation code TORIC (Brambilla 1999 Plasma Phys. Control. Fusion41 1 and Brambilla 2002 Plasma Phys. Control. Fusion44 2423), have been extended to allow the prescription of arbitrary velocity distributions of the form . For hydrogen (H) minority heating of a deuterium (D) plasma with anisotropic Maxwellian H distributions, the fractional H absorption varies significantly with changes in parallel temperature but is essentially independent of perpendicular temperature. On the other hand, for HHFW regime with anisotropic Maxwellian fast ion distribution, the fractional beam ion absorption varies mainly with changes in the perpendicular temperature. The evaluation of the wave-field and power absorption, through the full wave solver, with the ion distribution function provided by either a Monte-Carlo particle and Fokker–Planck codes is also examined for Alcator C-Mod and NSTX plasmas. Non-Maxwellian effects generally tend to increase the absorption with respect to the equivalent Maxwellian distribution. [ABSTRACT FROM AUTHOR]

Published

2017

27. Effects of MHD instabilities on neutral beam current drive.

Author

M. Podestà, M. Gorelenkova, D.S. Darrow, E.D. Fredrickson, S.P. Gerhardt, and R.B. White

Subjects

*MAGNETOHYDRODYNAMIC instabilities, *PLASMA beam injection heating, *TOKAMAKS, *PLASMA currents, *FUSION reactors, *PLASMA confinement

Abstract

Neutral beam injection (NBI) is one of the primary tools foreseen for heating, current drive (CD) and q-profile control in future fusion reactors such as ITER and a Fusion Nuclear Science Facility. However, fast ions from NBI may also provide the drive for energetic particle-driven instabilities (e.g. Alfvénic modes (AEs)), which in turn redistribute fast ions in both space and energy, thus hampering the control capabilities and overall efficiency of NB-driven current. Based on experiments on the NSTX tokamak (M. Ono et al 2000 Nucl. Fusion40 557), the effects of AEs and other low-frequency magneto-hydrodynamic instabilities on NB-CD efficiency are investigated. A new fast ion transport model, which accounts for particle transport in phase space as required for resonant AE perturbations, is utilized to obtain consistent simulations of NB-CD through the tokamak transport code TRANSP. It is found that instabilities do indeed reduce the NB-driven current density over most of the plasma radius by up to ∼50%. Moreover, the details of the current profile evolution are sensitive to the specific model used to mimic the interaction between NB ions and instabilities. Implications for fast ion transport modeling in integrated tokamak simulations are briefly discussed. [ABSTRACT FROM AUTHOR]

Published

2015

28. TRANSP modelling of total and local neutron emission on MAST.

Author

I. Klimek, D. Keeling, A. Meakins, M. Cecconello, G. Ericsson, O. Jones, M. Gorelenkova, R. Akers, I. Lupelli, Team, the MAST, and M. Turnyanskiy

Subjects

TOKAMAKS, NEUTRON emission, SIMULATION methods & models, DEUTERIUM ions, NUCLEAR fusion, PLASMA beam injection heating

Abstract

The results of TRANSP simulations of neutron count rate profiles measured by a collimated neutron flux monitor–neutron camera (NC)—for different plasma scenarios on MAST are reported. In addition, the effect of various plasma parameters on neutron emission is studied by means of TRANSP simulation. The fast ion redistribution and losses due to fishbone modes, which belong to a wider category of energetic particle modes, are observed by the NC and modelled in TRANSP. [ABSTRACT FROM AUTHOR]

Published

2015