Your search keyword '"TGLF"' showing total 9 results

1. Full radius integrated modelling of ohmic ramp-up at TCV including self consistent density prediction

Author

M. Marin, Y. Camenen, C. Bourdelle, F.J. Casson, R. Coosemans, L. Garzotti, P. Maget, P. Manas, A. Najlaoui, O. Sauter, and the TCV Team

Subjects

integrated modelling, ramp-up, QuaLiKiz, TGLF, validation, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

The ramp-up is a critical phase in the operations of a Tokamak, during which engineering and physics aspects must be taken into account to ensure stability, minimize flux consumption and avoid disruptions. Predicting ramp-up phases faces challenges such as nonlinearity, uncertainty on boundary and initial conditions and changes in the magnetic equilibrium. Our work uses the High-Fidelity Pulse Simulator (HFPS), a Python workflow based on JINTRAC. The input and output are in machine and code generic IMAS data format. The HFPS predicts the evolution of the current, temperature, main ion density and impurity density up to the separatrix. The self-consistent prediction of the density during the ramp-up represents the main element of novelty in this work. To this end, a closed feedback loop is set to match experimental line averaged density. QuaLiKiz (Citrin et al 2017 Plasma Phys. Control. Fusion 59 124005), TGLF (Staebler et al 2016 Phys. Plasmas 23 062518) and FRANTIC (Tamor 1981 J. Comput. Phys. 40 104119) are used to calculate turbulent fluxes and the source of neutrals respectively. QuaLiKiz and TGLF predict a transition from Trapped Electron Mode early in the discharge to Ion Temperature Gradient dominated turbulence. The results are compared to higher fidelity simulations with GKW, which show qualitative agreement. Good general agreement is reached between integrated modelling and experimental data, quantified by proposed measures of agreement. A large set of sensitivities to modelling choices and initial and boundary conditions is performed on four different discharges, to assess the robustness of the approach.

Published

2025

2. Validation of D–T fusion power prediction capability against 2021 JET D–T experiments.

Author

Kim, Hyun-Tae, Auriemma, Fulvio, Ferreira, Jorge, Gabriellini, Stefano, Ho, Aaron, Huynh, Philippe, Kirov, Krassimir, Lorenzini, Rita, Marin, Michele, Poradzinski, Michal, Shi, Nan, Staebler, Gary, Štancar, Žiga, Stankunas, Gediminas, Konrad Zotta, Vito, Belli, Emily, Casson, Francis J, D Challis, Clive, Citrin, Jonathan, and van Eester, Dirk

Subjects

*NUCLEAR fusion, *PREDICTIVE validity, *FORECASTING, *PREDICTION models, *MEASUREMENT errors, *STATISTICAL power analysis, *LARGE deviations (Mathematics), *NUCLEOSYNTHESIS, *JETS (Nuclear physics)

Abstract

JET experiments using the fuel mixture envisaged for fusion power plants, deuterium and tritium (D–T), provide a unique opportunity to validate existing D–T fusion power prediction capabilities in support of future device design and operation preparation. The 2021 JET D–T experimental campaign has achieved D–T fusion powers sustained over 5 s in ITER-relevant conditions i.e. operation with the baseline or hybrid scenario in the full metallic wall. In preparation of the 2021 JET D–T experimental campaign, extensive D–T predictive modelling was carried out with several assumptions based on D discharges. To improve the validity of ITER D–T predictive modelling in the future, it is important to use the input data measured from 2021 JET D–T discharges in the present core predictive modelling, and to specify the accuracy of the D–T fusion power prediction in comparison with the experiments. This paper reports on the validation of the core integrated modelling with TRANSP, JINTRAC, and ETS coupled with a quasilinear turbulent transport model (Trapped Gyro Landau Fluid or QualLiKiz) against the measured data in 2021 JET D–T discharges. Detailed simulation settings and the heating and transport models used are described. The D–T fusion power calculated with the interpretive TRANSP runs for 38 D–T discharges (12 baseline and 26 hybrid discharges) reproduced the measured values within 20 %. This indicates the additional uncertainties, that could result from the measurement error bars in kinetic profiles, impurity contents and neutron rates, and also from the beam-thermal fusion reaction modelling, are less than 20 % in total. The good statistical agreement confirms that we have the capability to accurately calculate the D–T fusion power if correct kinetic profiles are predicted, and indicates that any larger deviation of the D–T fusion power prediction from the measured fusion power could be attributed to the deviation of the predicted kinetic profiles from the measured kinetic profiles in these plasma scenarios. Without any posterior adjustment of the simulation settings, the ratio of predicted D–T fusion power to the measured fusion power was found as 65%–96% for the D–T baseline and 81%–97% for D–T hybrid discharge. Possible reasons for the lower D–T prediction are discussed and future works to improve the fusion power prediction capability are suggested. The D–T predictive modelling results have also been compared to the predictive modelling of the counterpart D discharges, where the key engineering parameters are similar. Features in the predicted kinetic profiles of D–T discharges such as underprediction of ne are also found in the prediction results of the counterpart D discharges, and it leads to similar levels of the normalized neutron rate prediction between the modelling results of D–T and the counterpart D discharges. This implies that the credibility of D–T fusion power prediction could be a priori estimated by the prediction quality of the preparatory D discharges, which will be attempted before actual D–T experiments. [ABSTRACT FROM AUTHOR]

Published

2023

3. Ti/Te effects on transport in EAST low q95 plasmas

Author

Y.F. He, J.P. Qian, J.G. Li, P. Li, X.Z. Gong, B. Zhang, J.Y. Zhang, J.L. Chen, Cheonho Bae, M.Q. Wu, X.D. Yang, T.Q. Jia, G.S. Li, Y.F. Jin, Z.C. Lin, S.Y. Fu, G.L. Lin, Q. Zang, G.Q. Zhong, S.X. Wang, X. Li, and J. Huang

Subjects

Ti/Te, transport and confinement, ITG mode, TGLF, EAST, turbulence, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

Enhanced confinement is observed in EAST low ${q_{95}}$ ( ${q_{95}} < 3.5$ ) plasmas with the temperature ratio ( ${T_i}/{T_e}$ ) increasing. A statistically significant positive correlation between ${H_{98y2}}$ and ${T_i}/{T_e}$ has been established. Increased ${T_i}\,$ triggerd by Neutral Beam Injection in experiments maintaining constant ${T_e}$ leads initially to an improved ${T_i}/{T_e}$ ratio, which subsequently mitigates heat transport in the ion channel. The Trapped Gyro–Landau Fluid transport model was applied to analyse the dependence of the turbulent transport on ${T_i}/{T_e}$ . Simulation results demonstrate that the Ion Temperature Gradient mode is stabilized in high ${T_i}/{T_e}$ plasma, with ion flux results from predictive modelling further validating this effect. These findings corroborate the Weiland model and complement one another. This study contributes to a deeper understanding of how the dimensionless parameter ${T_i}/{T_e}$ influences plasma transport, and helps demonstrate the feasibility of operations under the low ${q_{95}}$ condition required for the ITER-inductive scenario in the new ${T_i}/{T_e}$ regime.

Published

2024

4. The feasibility of the L-H transition for a purely electron-heated EU-DEMO tokamak

Author

G. Suárez López, G. Tardini, E. Fable, M. Siccinio, and H. Zohm

Subjects

L-H transition, DEMO, ASTRA, TGLF, L-mode, H-mode, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

We study numerically the feasibility of achieving the L-H transition in the current EU-DEMO tokamak baseline using uniquely direct electron heating. The ASTRA code coupled to the TGLF turbulent transport model is used to predict steady-state kinetic plasma profiles for diverse numerical scans. Among them, we have varied the separatrix electron density, the total amount of ECRH power, the microwave beam deposition profile and the plasma impurity content. The solutions are then compared to L-H transition scaling laws to assess whether the found plasma state would enter into H-mode. We find the plasma density and impurity content to be the key variables setting the boundaries in parameter space where the L-H transition is feasible. When impurities can be controlled under a certain threshold, given here for a fully shaped DEMO plasma, the L-H transition is achieved in all the studied conditions.

Published

2024

5. Energy transport analysis of NSTX plasmas with the TGLF turbulent and NEO neoclassical transport models

Author

G. Avdeeva, K.E. Thome, S.P. Smith, D.J. Battaglia, C.F. Clauser, W. Guttenfelder, S.M. Kaye, J. McClenaghan, O. Meneghini, T. Odstrcil, and G. Staebler

Subjects

NSTX, TGLF, NEO, energy transport analysis, electrostatic drift-wave instabilities, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

This work presents a study of plasma transport at low aspect ratio on the National Spherical Torus Experiment tokamak, where the turbulent and neoclassical energy fluxes calculated by the quasilinear Trapped Gyro Landau Fluid (TGLF) model and the multi species drift-kinetic Neoclassical solver (NEO) are validated against experimental data. The turbulent energy transport of two plasma discharges, one in the L-mode confinement regime and another in the H-mode regime, is dominated by electrostatic drift-wave instabilities, while the ion heat transport has a significant neoclassical contribution. The data analysis workflow is described in detail to understand how the variations of mapping and fitting of experimental data affect the power balance solution and subsequent flux-matching plasma profile predictions with the TGYRO solver. On average, the predicted plasma profiles are consistent with experimental data. However, the solutions are sensitive to various input parameters, including boundary conditions, and the electron-ion coupling. Linear gyrokinetic stability analysis demonstrates close agreement of the real frequencies of unstable modes between TGLF and CGYRO gyrokinetic simulations, but higher growth rates are predicted by TGLF, especially for the H-mode case. Estimates of the low- k modes’ contributions to the total flux are consistent with linear stability analysis and the E × B suppression of turbulence in TGLF simulations with the SAT1 saturation model, while the SAT2 saturation model over-predicts the low- k modes’ contribution in the H-mode case. Moreover, the results with SAT1 model are consistent with power balance analysis, which indicates only neoclassical ion energy fluxes inside ρ

Published

2023

6. Validation of D-T fusion power prediction capability against 2021 JET D-T experiments

Author

Kim, H, Auriemma, F, Ferreira, J, Gabriellini, S, Ho, A, Huynh, P, Kirov, K, Lorenzini, R, Marin, M, Poradzinski, M, Shi, N, Staebler, G, Stancar, Z, Stankunas, G, Zotta, V, Belli, E, Casson, F, Challis, C, Citrin, J, van Eester, D, Fransson, E, Gallart, D, Garcia, J, Garzotti, L, Gatto, R, Hobirk, J, Kappatou, A, Lerche, E, Ludvig-Osipov, A, Maggi, C, Maslov, M, Nocente, M, Sharma, R, Di Siena, A, Strand, P, Tholerus, E, Yadykin, D, Kim, HT, Ho, AR, Zotta, VK, Casson, FJ, Kim, H, Auriemma, F, Ferreira, J, Gabriellini, S, Ho, A, Huynh, P, Kirov, K, Lorenzini, R, Marin, M, Poradzinski, M, Shi, N, Staebler, G, Stancar, Z, Stankunas, G, Zotta, V, Belli, E, Casson, F, Challis, C, Citrin, J, van Eester, D, Fransson, E, Gallart, D, Garcia, J, Garzotti, L, Gatto, R, Hobirk, J, Kappatou, A, Lerche, E, Ludvig-Osipov, A, Maggi, C, Maslov, M, Nocente, M, Sharma, R, Di Siena, A, Strand, P, Tholerus, E, Yadykin, D, Kim, HT, Ho, AR, Zotta, VK, and Casson, FJ

Abstract

JET experiments using the fuel mixture envisaged for fusion power plants, deuterium and tritium (D-T), provide a unique opportunity to validate existing D-T fusion power prediction capabilities in support of future device design and operation preparation. The 2021 JET D-T experimental campaign has achieved D-T fusion powers sustained over 5 s in ITER-relevant conditions i.e. operation with the baseline or hybrid scenario in the full metallic wall. In preparation of the 2021 JET D-T experimental campaign, extensive D-T predictive modelling was carried out with several assumptions based on D discharges. To improve the validity of ITER D-T predictive modelling in the future, it is important to use the input data measured from 2021 JET D-T discharges in the present core predictive modelling, and to specify the accuracy of the D-T fusion power prediction in comparison with the experiments. This paper reports on the validation of the core integrated modelling with TRANSP, JINTRAC, and ETS coupled with a quasilinear turbulent transport model (Trapped Gyro Landau Fluid or QualLiKiz) against the measured data in 2021 JET D-T discharges. Detailed simulation settings and the heating and transport models used are described. The D-T fusion power calculated with the interpretive TRANSP runs for 38 D-T discharges (12 baseline and 26 hybrid discharges) reproduced the measured values within 20 % . This indicates the additional uncertainties, that could result from the measurement error bars in kinetic profiles, impurity contents and neutron rates, and also from the beam-thermal fusion reaction modelling, are less than 20 % in total. The good statistical agreement confirms that we have the capability to accurately calculate the D-T fusion power if correct kinetic profiles are predicted, and indicates that any larger deviation of the D-T fusion power prediction from the measured fusion power could be attributed to the deviation of the predicted kinetic profiles from the measured kinet

Published

2023

7. H-mode characterisation for dominant ECRH and comparison to dominant NBI or ICRF heating at ASDEX Upgrade.

Author

Sommer, F., Stober, J., Angioni, C., Fable, E., Bernert, M., Burckhart, Bobkov, V., Fischer, R., Fuchs, C., McDermott, R. M., Suttrop, W., and Viezzer, E.

Subjects

*H-mode plasma confinement, *ELECTRON-ion collisions, *HEAT transfer, *ION channels, *ION temperature, *ELECTRON cyclotron resonance heating, *PLASMA heating, *CYCLOTRON resonance

Abstract

At ASDEX Upgrade the ECRH system has been upgraded to provide up to 4 MW of heating power at 140 GHz (or 2:2 MW at 105 GHz). The power at 140 GHz exceeds the minimum H-mode power threshold for typical high Ip; Bt conditions by approximately a factor of two. The upgrade allows H-modes with dominant electron heating and significant electron-ion heat exchange to be studied, i.e. the situation expected in ITER. This paper reports on systematic studies varying the heating mix with NBI, ICRF and ECRH and its effect on pedestal parameters and core transport. The H-mode pedestal is hardly affected by the choice of heating mix, but the ion temperature in the plasma center is found to vary significantly. The ion channel dominates heat transport and ion temperature gradient modes (ITG) are found to be the most unstable microinstability in all the scenarios considered. R/LTi at half radius reduces by a factor of two when Te/Ti increases from 0.9 to 1.5. TGLF modelling of the electron and ion temperature and electron density profiles shows very good agreement with the experimental data when applying a realistic sawtooth model. [ABSTRACT FROM AUTHOR]

Published

2014

8. Validation of TGLF predictive capability on baseline high performance JET Deuterium plasmas and extrapolation to DT

Author

Auriemma F., Kim H-T., Garzotti L., Lorenzini R., Staebler G., and JET contributors

Subjects

JET, Deuterium plasmas, TGLF

Abstract

One of the key aspects for future fusion reactors is the understanding of plasma behaviour with different hydrogen isotopes, the so called isotope effects. Since 80s, experimental and modelling efforts have been dedicated to understand the isotope effects. The upcoming JET-DT campaign gives the unique opportunity of comparing and validating the state of the art of modelling tools with fusion relevant DT plasmas. To prepare the 2021 JET-DT experimental campaign and to predict the plasma performance, an extensive modelling activity has been carried out. This work reports about the validation of the TGLF transport model: several Deuterium (DD) high performing baseline discharges have been analysed by running TRANSP integrated modelling simulations with a couple of saturation rules in TGLF (SAT1 and SAT1geo). In particular SAT1geo has been modified with respect to SAT1, with the effect of increasing the ion stiffness and reducing the ExB stabilization, generally predicting higher fluxes and hence milder profiles. The discharges included in the analysis have plasma current from 3.0 to 3.4 MA, Bt = [2.8-3.4] T and total input power Pin=[26-34] MW, with steady state high neutron rate phase lasting for several energy confinement times. For each discharge, the content of each impurity and the radiation profile have been measured by soft-X ray analysis, including Be, Ne, Ni and W. Also the rotation profile is input in the model, whereas electron density ne, temperature Te and ion temperature Ti are predicted. The work aims at identifying the model capability of matching the experimental Te, ne and Ti profiles in the core and confinement regions, r=[0,0.8]. Also the temporal evolution of absolute value of neutron rate and line integral density has been included in the analysis, to consider volume effects. After an initial tuning of TGLF, no modifications at the transport model settings have been applied, apart from the saturation rule in TGLF. In general the profiles and neutron rates predicted with SAT1 show a better agreement with experimental data, whereas SAT1geo obtains a good match only in some specific time interval, in particular with the ne profile. The temporal trends of global quantities are well reproduced, but a negative offset (decrease in performance) is often predicted by SAT1geo at the beginning of the profiles prediction, suggesting an overestimate of the predicted fluxes with respect to the experimental ones. On these bases, the saturation rule SAT1 has been selected to extrapolate DD baseline plasmas to DT, resulting in about 10 MW of fusion power at Pin=33MW and about 14MW at Pin=40MW.

Published

2021

9. Statistical validation of predictive TRANSP simulations of baseline discharges in preparation for extrapolation to JET D-T

Author

Kim, Hyun-Tae, Andersson Sundén, Erik, Binda, Federico, Cecconello, Marco, Conroy, Sean, Dzysiuk, Nataliia, Ericsson, Göran, Eriksson, Jacob, Hellesen, Carl, Hjalmarsson, Anders, Possnert, Göran, Sjöstrand, Henrik, Skiba, Mateusz, Weiszflog, Matthias, Zychor, I., Kim, Hyun-Tae, Andersson Sundén, Erik, Binda, Federico, Cecconello, Marco, Conroy, Sean, Dzysiuk, Nataliia, Ericsson, Göran, Eriksson, Jacob, Hellesen, Carl, Hjalmarsson, Anders, Possnert, Göran, Sjöstrand, Henrik, Skiba, Mateusz, Weiszflog, Matthias, and Zychor, I.

Abstract

This paper presents for the first time a statistical validation of predictive TRANSP simulations of plasma temperature using two transport models, GLF23 and TGLF, over a database of 80 baseline H-mode discharges in JET-ILW. While the accuracy of the predicted Te with TRANSP-GLF23 is affected by plasma collisionality, the dependency of predictions on collisionality is less significant when using TRANSP-TGLF, indicating that the latter model has a broader applicability across plasma regimes. TRANSP-TGLF also shows a good matching of predicted Ti with experimental measurements allowing for a more accurate prediction of the neutron yields. The impact of input data and assumptions prescribed in the simulations are also investigated in this paper. The statistical validation and the assessment of uncertainty level in predictive TRANSP simulations for JET-ILW-DD will constitute the basis for the extrapolation to JET-ILW-DT experiments., For complete list of authors see http://dx.doi.org/10.1088/1741-4326/aa6b80

Published

2017