Towards large databases analysis for reactors-relevant studies on high electron temperature measurement discrepancy

Luca Senni; F. P. Orsitto; G. Giruzzi; D. Mazon; S. Mazzi; M. Fontana; E. Giovannozzi; D. Kos; M. Maslov; C. Challis; D. Frigione; L. Garzotti; J. Hobirk; A. Kappatou; D. Keeling; E. Lerche; C. Maggi; J. Mailloux; F. Rimini; D. Van Eester; Jet contributors

doi:10.1088/1748-0221/21/04/C04069

Towards large databases analysis for reactors-relevant studies on high electron temperature measurement discrepancy

Luca Senni
, F. P. Orsitto
, G. Giruzzi
, D. Mazon
, S. Mazzi
, M. Fontana
, E. Giovannozzi
, D. Kos
, M. Maslov
, C. Challis
, D. Frigione
, L. Garzotti
, J. Hobirk
, A. Kappatou
, D. Keeling
, E. Lerche
, C. Maggi
, J. Mailloux
, F. Rimini
, D. Van Eester

Jet contributors

Laboratory for Plasma Physics

CNR
Sapienza University of Rome
ENEA Centro Ricerche Frascati
Commissariat à l'Énergie Atomique (CEA)
Tokamak Energy Ltd
EURATOM-UKAEA Association Culham Science Centre
University of Rome Tor Vergata
Max-Planck-Institut für Plasmaphysik
Royal Military Academy

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

Abstract

Accurate electron temperature (Te) measurements are critical for future reactors such as ITER, CFETR, and DEMO, where core T _e is expected to exceed 25 keV [1-3]. However, in current tokamaks, core electron temperature measurements become increasingly challenging at high values (typically above 6–7 keV), where discrepancies frequently arise between diagnostics such as Thomson Scattering (TS) and Electron cyclotron emission (ECE). These discrepancies highlight both a diagnostic challenge and an opportunity to deepen the understanding of core plasma physics. Recent studies have provided further insights into these phenomena, clarifying key physical aspects, and yielding more substantial results [4-8]. Nevertheless, a broader experimental database remains essential to validate and support the physical hypotheses developed in recent years. This contribution reports on preliminary results obtained from the analysis of the entire JET-DTE3 dataset, providing a status update on our ongoing research. Specifically, we focus on the methodological advancements and the analytical tools recently developed to manage the unprecedented volume of data within the DTE3 database. This framework enables a deep investigation into the T _e discrepancy, marking the first time this phenomenon has been systematically studied across such an extensive and statistically significant dataset. This work is conducted within the framework of the International Tokamak Physics Activity (ITPA) JEX#17 on `High Electron Temperature Measurements', which aims to compare data collected across multiple fusion devices to systematically identify the origin of the observed Te discrepancy.

Originalsprache	Englisch
Fachzeitschrift	Journal of Instrumentation
Jahrgang	21
Ausgabenummer	4
DOIs	https://doi.org/10.1088/1748-0221/21/04/C04069
Publikationsstatus	Veröffentlicht - Apr. 2026

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10.1088/1748-0221/21/04/C04069

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Senni, L., Orsitto, F. P., Giruzzi, G., Mazon, D., Mazzi, S., Fontana, M., Giovannozzi, E., Kos, D., Maslov, M., Challis, C., Frigione, D., Garzotti, L., Hobirk, J., Kappatou, A., Keeling, D., Lerche, E., Maggi, C., Mailloux, J., Rimini, F., ... contributors, J. (2026). Towards large databases analysis for reactors-relevant studies on high electron temperature measurement discrepancy. Journal of Instrumentation, 21(4). https://doi.org/10.1088/1748-0221/21/04/C04069

@article{1433838179224a6191738cc61020104e,

title = "Towards large databases analysis for reactors-relevant studies on high electron temperature measurement discrepancy",

abstract = "Accurate electron temperature (Te) measurements are critical for future reactors such as ITER, CFETR, and DEMO, where core T e is expected to exceed 25 keV [1-3]. However, in current tokamaks, core electron temperature measurements become increasingly challenging at high values (typically above 6–7 keV), where discrepancies frequently arise between diagnostics such as Thomson Scattering (TS) and Electron cyclotron emission (ECE). These discrepancies highlight both a diagnostic challenge and an opportunity to deepen the understanding of core plasma physics. Recent studies have provided further insights into these phenomena, clarifying key physical aspects, and yielding more substantial results [4-8]. Nevertheless, a broader experimental database remains essential to validate and support the physical hypotheses developed in recent years. This contribution reports on preliminary results obtained from the analysis of the entire JET-DTE3 dataset, providing a status update on our ongoing research. Specifically, we focus on the methodological advancements and the analytical tools recently developed to manage the unprecedented volume of data within the DTE3 database. This framework enables a deep investigation into the T e discrepancy, marking the first time this phenomenon has been systematically studied across such an extensive and statistically significant dataset. This work is conducted within the framework of the International Tokamak Physics Activity (ITPA) JEX\#17 on `High Electron Temperature Measurements', which aims to compare data collected across multiple fusion devices to systematically identify the origin of the observed Te discrepancy.",

keywords = "Analysis and statistical methods, Data processing methods, Nuclear instruments and methods for hot plasma diagnostics, Plasma diagnostics - charged-particle spectroscopy",

author = "Luca Senni and Orsitto, \{F. P.\} and G. Giruzzi and D. Mazon and S. Mazzi and M. Fontana and E. Giovannozzi and D. Kos and M. Maslov and C. Challis and D. Frigione and L. Garzotti and J. Hobirk and A. Kappatou and D. Keeling and E. Lerche and C. Maggi and J. Mailloux and F. Rimini and \{Van Eester\}, D. and Jet contributors",

note = "Publisher Copyright: {\textcopyright} 2026 The Author(s). Published by IOP Publishing Ltd on behalf of Sissa Medialab. Original content from this work may be used under the terms of the http://creativecommons.org/licenses/by/4.0. Any further distribution of this work must maintain attribution to the author(s) and the title of the work, journal citation and DOI.",

year = "2026",

month = apr,

doi = "10.1088/1748-0221/21/04/C04069",

language = "English",

volume = "21",

journal = "Journal of Instrumentation",

issn = "1748-0221",

number = "4",

}

Senni, L, Orsitto, FP, Giruzzi, G, Mazon, D, Mazzi, S, Fontana, M, Giovannozzi, E, Kos, D, Maslov, M, Challis, C, Frigione, D, Garzotti, L, Hobirk, J, Kappatou, A, Keeling, D, Lerche, E, Maggi, C, Mailloux, J, Rimini, F, Van Eester, D & contributors, J 2026, 'Towards large databases analysis for reactors-relevant studies on high electron temperature measurement discrepancy', Journal of Instrumentation, Jg. 21, Nr. 4. https://doi.org/10.1088/1748-0221/21/04/C04069

TY - JOUR

T1 - Towards large databases analysis for reactors-relevant studies on high electron temperature measurement discrepancy

AU - Senni, Luca

AU - Orsitto, F. P.

AU - Giruzzi, G.

AU - Mazon, D.

AU - Mazzi, S.

AU - Fontana, M.

AU - Giovannozzi, E.

AU - Kos, D.

AU - Maslov, M.

AU - Challis, C.

AU - Frigione, D.

AU - Garzotti, L.

AU - Hobirk, J.

AU - Kappatou, A.

AU - Keeling, D.

AU - Lerche, E.

AU - Maggi, C.

AU - Mailloux, J.

AU - Rimini, F.

AU - Van Eester, D.

AU - contributors, Jet

N1 - Publisher Copyright: © 2026 The Author(s). Published by IOP Publishing Ltd on behalf of Sissa Medialab. Original content from this work may be used under the terms of the http://creativecommons.org/licenses/by/4.0. Any further distribution of this work must maintain attribution to the author(s) and the title of the work, journal citation and DOI.

PY - 2026/4

Y1 - 2026/4

N2 - Accurate electron temperature (Te) measurements are critical for future reactors such as ITER, CFETR, and DEMO, where core T e is expected to exceed 25 keV [1-3]. However, in current tokamaks, core electron temperature measurements become increasingly challenging at high values (typically above 6–7 keV), where discrepancies frequently arise between diagnostics such as Thomson Scattering (TS) and Electron cyclotron emission (ECE). These discrepancies highlight both a diagnostic challenge and an opportunity to deepen the understanding of core plasma physics. Recent studies have provided further insights into these phenomena, clarifying key physical aspects, and yielding more substantial results [4-8]. Nevertheless, a broader experimental database remains essential to validate and support the physical hypotheses developed in recent years. This contribution reports on preliminary results obtained from the analysis of the entire JET-DTE3 dataset, providing a status update on our ongoing research. Specifically, we focus on the methodological advancements and the analytical tools recently developed to manage the unprecedented volume of data within the DTE3 database. This framework enables a deep investigation into the T e discrepancy, marking the first time this phenomenon has been systematically studied across such an extensive and statistically significant dataset. This work is conducted within the framework of the International Tokamak Physics Activity (ITPA) JEX#17 on `High Electron Temperature Measurements', which aims to compare data collected across multiple fusion devices to systematically identify the origin of the observed Te discrepancy.

AB - Accurate electron temperature (Te) measurements are critical for future reactors such as ITER, CFETR, and DEMO, where core T e is expected to exceed 25 keV [1-3]. However, in current tokamaks, core electron temperature measurements become increasingly challenging at high values (typically above 6–7 keV), where discrepancies frequently arise between diagnostics such as Thomson Scattering (TS) and Electron cyclotron emission (ECE). These discrepancies highlight both a diagnostic challenge and an opportunity to deepen the understanding of core plasma physics. Recent studies have provided further insights into these phenomena, clarifying key physical aspects, and yielding more substantial results [4-8]. Nevertheless, a broader experimental database remains essential to validate and support the physical hypotheses developed in recent years. This contribution reports on preliminary results obtained from the analysis of the entire JET-DTE3 dataset, providing a status update on our ongoing research. Specifically, we focus on the methodological advancements and the analytical tools recently developed to manage the unprecedented volume of data within the DTE3 database. This framework enables a deep investigation into the T e discrepancy, marking the first time this phenomenon has been systematically studied across such an extensive and statistically significant dataset. This work is conducted within the framework of the International Tokamak Physics Activity (ITPA) JEX#17 on `High Electron Temperature Measurements', which aims to compare data collected across multiple fusion devices to systematically identify the origin of the observed Te discrepancy.

KW - Analysis and statistical methods

KW - Data processing methods

KW - Nuclear instruments and methods for hot plasma diagnostics

KW - Plasma diagnostics - charged-particle spectroscopy

UR - https://www.scopus.com/pages/publications/105037771299

U2 - 10.1088/1748-0221/21/04/C04069

DO - 10.1088/1748-0221/21/04/C04069

M3 - Article

AN - SCOPUS:105037771299

SN - 1748-0221

VL - 21

JO - Journal of Instrumentation

JF - Journal of Instrumentation

IS - 4

ER -

Towards large databases analysis for reactors-relevant studies on high electron temperature measurement discrepancy

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