Your search keyword '"Luca Garzotti"' showing total 8 results

1. Nuclear fusion: it's time for a reality check; Significant obstacles lie ahead in the quest for commercially viable nuclear fusion, writes Luca Garzotti

Subjects

News, opinion and commentary

Abstract

I can't help thinking Ed Miliband has not been accurately briefed when he says a government funding pledge means Britain is within 'grasping distance' of 'secure, clean, unlimited energy' from [...]

Published

2025

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

Author

Hyun-Tae Kim, Fulvio Auriemma, Jorge Ferreira, Stefano Gabriellini, Aaron Ho, Philippe Huynh, Krassimir Kirov, Rita Lorenzini, Michele Marin, Michal Poradzinski, Nan Shi, Gary Staebler, Žiga Štancar, Gediminas Stankunas, Vito Konrad Zotta, Emily Belli, Francis J Casson, Clive D Challis, Jonathan Citrin, Dirk van Eester, Emil Fransson, Daniel Gallart, Jeronimo Garcia, Luca Garzotti, Renato Gatto, Joerg Hobirk, Athina Kappatou, Ernesto Lerche, Andrei Ludvig-Osipov, Costanza Maggi, Mikhail Maslov, Massimo Nocente, Ridhima Sharma, Alessandro Di Siena, Par Strand, Emmi Tholerus, Dimitriy Yadykin, and JET Contributors

Subjects

JET D–T, fusion power prediction, TGLF, QuaLiKiz, TRANSP, JINTRAC, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

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 n _e 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.

Published

2023

3. ECRF stray radiation studies in preparation of the operations of JT-60SA

Author

Carlo Sozzi, Ken Kajiwara, Takayuki Kobayashi, Lorenzo Figini, Luca Garzotti, Alessandro Moro, Silvana Nowak, and David Taylor

Subjects

General Medicine

Abstract

JT-60SA tokamak is equipped with an ECRF system since the beginning of its operational phase. Starting from two gyrotrons units during the Integrated Commissioning, applicable for core heating, assisted breakdown and assisted Wall Conditioning, the system capabilities will be progressively extended from the Initial Research phase for wider applications. The development of the full current plasma H mode scenario 2 (inductive, type I ELM, Ip=5.5 MA, BT=2.25 T, q95=3) is among the first scientific objectives of the research program. In preparation of this, predictive modelling of the current ramp-up in scaled versions of scenario 2 is being done, based on parameters previously published. In this scenario the ECRF power is injected from an early phase of the discharge. Such modelling provides the kinetic profiles giving the opportunity to estimate the expected amount of EC stray radiation during the ramp-up phase when the EC power absorption might be less than 100% and consequently the potential risk of damage of the in-vessel components is higher.

Published

2023

4. Cold fusion may a viable energy alternative to end reliance on fossil fuels; A number of companies have been able to make these low-energy nuclear reactions work reliably, write Brian Josephson, David J Nagel, Alan Smith, Dr Jean-Paul BiberianandYasuhiro Iwamura

Subjects

Energy minerals, Fossil fuels, Nuclear physics

Abstract

Luca Garzotti observes ( Letters, 22 January ) that serious challenges face the production of energy from processes based on thermonuclear fusion, but failed to mention a crucially important alternative, […]

Published

2025

5. High Te discrepancies between ECE and Thomson diagnostics in high-performance JET discharges.

Author

Fontana, M., Giruzzi, G., Orsitto, F. P., de la Luna, E., Dumont, R., Figini, L., Kos, D., Maslov, M., Schmuck, S., Senni, L., Sozzi, C., Frigione, D., Garcia, J., Garzotti, L., Hobirk, J., Kappatou, A., Keeling, D., Lerche, E., Rimini, F., and Van Eester, D.

Subjects

DISTRIBUTION (Probability theory), ELECTRON emission, THOMSON scattering, ELECTRON distribution, ELECTRON temperature, DEUTERIUM, HARMONIC maps

Abstract

The present paper is dedicated to the study of the discrepancies encountered in electron temperature (Te) measurements carried out with electron cyclotron emission (ECE) and Thomson scattering (TS) diagnostics in the core of the JET tokamak. A large database of discharges has been collected, including high-performance scenarios performed with deuterium only and deuterium–tritium mixtures. Discrepancies have been found between core Te measurements taken with an X-mode ECE interferometer (TECE) and a LIDAR TS system (TLID) for T e > 5 keV. Depending on the plasma scenario, TECE has been found to be systematically higher or lower than TLID. Discrepancies have also been observed between the peaks of the ECE spectrum in the second (X2) and third (X3) harmonic domains, even in high optical thickness conditions. These discrepancies can be interpreted as evidence of the presence of non-Maxwellian features in the electron energy distribution function (EEDF). In order to investigate the relation between the shape of the EEDF and the measured discrepancies, a model for bipolar perturbations of Maxwellian EEDF has been developed. The model allows analytical calculations of ECE absorption and emission coefficients; hence, the comparison of modeled ECE spectra with experimental data. The different experimental results observed for the various JET scenarios have been found to be qualitatively reproducible by adapting the model parameters, suggesting that bipolar distortions of the bulk EEDF could play a role in giving rise to the reported discrepancies between ECE and TS measurements. [ABSTRACT FROM AUTHOR]

Published

2023

6. 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

7. Core‐SOL simulations of high‐power JET‐ILW pulses fuelled with gas and/or with pellets.

Author

Telesca, Giuseppe, Chomiczewska, Agata, Frigione, Domenico, Garzotti, Luca, Huber, Alexander, Ivanova‐Stanik, Irena, Kowalska‐Strzeciwilk, Ewa, Lomas, Peter, Perez von Thun, Christian, Rimini, Fernanda, Van Eester, Dirk, and Zagórski, Roman

Subjects

GAS as fuel, ELECTRON density, THYRISTORS, FUSION reactor divertors

Abstract

Experimental analysis of two couples of pulses in the range of input power of 26–32 MW, shows that addition of pellet throughput to high gas dosing pulses does not modify the plasma energy, but leads to better conditions as far as the tungsten concentration and core radiation are concerned. Significantly decreasing the gas dosing with addition of high pellet throughput causes the increase of plasma energy, but the W concentration increases from 5.2 × 10−5 to 6.9 × 10−5 and the core radiation from 7.5 to 11 MW. From the numerical results of the self‐consistent core‐SOL COREDIV code two mechanisms appear to be responsible for the observed different W concentrations: the core residence time of W, which is related to the energy and particle confinement time, and the divertor impurity screening efficiency, dependent on the electron density and on the perpendicular transport coefficient in the SOL. [ABSTRACT FROM AUTHOR]

Published

2022

8. An Unsupervised Spectrogram Cross-Correlation Method to Assess ELM Triggering Efficiency by Pellets.

Author

Rossi, Riccardo, Cesaroni, Silvia, Bombarda, Francesca, Gaudio, Pasquale, Gelfusa, Michela, Marinelli, Marco, Verona Rinati, Gianluca, and Peluso, Emmanuele

Subjects

FUSION reactors, NUCLEAR fusion, NUCLEAR energy, ARTIFICIAL diamonds, SPECTROGRAMS, PLASMA confinement

Abstract

The high confinement mode (H-mode) is considered the optimal regime for the production of energy through nuclear fusion for industrial purposes since it allows to increase the energy confinement time of the plasma roughly by a factor of two. Consequently, it has been selected at the moment as the standard scenario for the next generation of devices, such as ITER. However, pressure-driven edge instabilities, known as edge localized modes (ELMs), are a distinct feature of this plasma regime. Their extrapolated thermal and particle peak loads on the plasma-facing components (PFC) of the next generation of devices are expected to be so high as to damage such structures, compromising the normal operations of the reactors themselves. Consequently, the induced loads have to be controlled; this can be achieved by mitigating ELMs. A possibility then lays in increasing the ELMs frequency to lower the loads on the PFCs. As already demonstrated at JET, the pellet pacing of ELMs is considered one of the most promising techniques for such scope, and its optimization is therefore of great interest for present and future operations of nuclear fusion facilities. In this work, we suggest a method to access primary pieces of information to perform statistics, assess and characterize the pacing efficiency. The method, tested on JET data, is based on the clustering (k-means) of convoluted signals, using so-called spectrogram cross-correlation, between the measured pellets and ELMs time traces. Results have also been obtained by taking advantage of a new type of diagnostic for measuring the ELMs dynamic, based on synthetic diamond sensors, faster than the standard spectroscopic cameras used at JET. [ABSTRACT FROM AUTHOR]

Published

2022