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Overview of coupled plasma-neutronics integrated modelling for D-T, D, and He plasmas in JET and ITER

ORAL

Abstract

Accurate measurements and computational predictions of fusion power are essential for developing and sustaining burning plasma conditions in magnetically confined devices. This contribution is an overview of a decade's worth of work on developing integrated modelling workflows for coupled plasma-neutronics simulations, enhancing the fidelity of fusion yield measurements and extrapolations for future fusion reactors, such as ITER, DEMO, and SPARC. The international collaborative effort utilizes state-of-the-art plasma transport (TRANSP, JINTRAC), orbit tracking (NUBEAM, LOCUST GPU), kinematics (DRESS), and neutronics codes (MCNP) to produce first-of-a-kind high-fidelity neutron and gamma source models. These are based on interpretive and predictive plasma simulations, with bespoke neutron sources computed and validated for individual plasma discharges. The source models are used in support of in-situ Pfus calibration procedures, synthetic diagnostics codes, neutron and photon transport shielding and radiation safety studies, and surrogate models for fusion performance estimates. We detail the application and validation of coupled plasma-neutronics workflows on JET D plasmas with MeV-range fast ions driving large neutron spectrum anisotropies, recent JET D-T plasmas that produced record fusion yields, JET He plasmas with neutron emission dominanted by fusion between energetic protons and metallic beryllium impurities, and ITER's baseline 15 MA/5.3 T D-T scenario based on core-SOL-divertor coupled JINTRAC simulations demonstrating Qfus ≈ 10.

Publication: - "Experimental observation and integrated modelling of proton-beryllium fusion in He and D plasmas at JET" to be submitted to Nuclear Fusion<br>- "Integrated modelling of the neutron source in ITER's baseline D-T scenario" to be submitted to Nuclear Fusion

Presenters

  • Žiga Štancar

    United Kingdom Atomic Energy Authority, Culham Campus, Abingdon, UK, UKAEA

Authors

  • Žiga Štancar

    United Kingdom Atomic Energy Authority, Culham Campus, Abingdon, UK, UKAEA

  • Jacob Eriksson

    Uppsala University

  • James Oliver

    UKAEA

  • Zamir Ghani

    UKAEA

  • Marina Gorelenkova

    Princeton Plasma Physics Laboratory (PPPL)

  • Anders Hjalmarsson

    Uppsala University

  • Sean Conroy

    Uppsala University

  • Andrej Žohar

    Jožef Stefan Institute

  • Yevgen Kazakov

    Laboratory for Plasma Physics, LPP-ERM/KMS, TEC Partner, 1000 Brussels, Belgium

  • Vasili Kiptily

    United Kingdom Atomic Energy Authority, Culham Campus, Abingdon, UK, UKAEA

  • Krassimir Kirov

    United Kingdom Atomic Energy Authority, Culham Campus, Abingdon, UK, UK Atomic Energy Authority (UKAEA)

  • Ernesto Lerche

    Laboratory for Plasma Physics LPP-ERM/KMS, B-1000 Brussels, Belgium

  • Xavier LITAUDON

    CEA

  • Evie Litherland-Smith

    United Kingdom Atomic Energy Authority, Culham Campus, Abingdon, UK

  • Mikhail Maslov

    United Kingdom Atomic Energy Authority, Culham Campus, Abingdon, UK, United Kingdom Atomic Energy Authority, Culham Centre for Fusion Energy, Culham Science Centre, Abingdon, Oxon, OX14 3DB, UK

  • Sheena Menmuir

    United Kingdom Atomic Energy Authority, Culham Campus, Abingdon, UK

  • Hongjuan Sun

    United Kingdom Atomic Energy Authority, Culham Campus, Abingdon, UK

  • Gabor Szepesi

    UKAEA Culham Campus

  • Rosaria Villari

    ENEA

  • Vito Konrad Zotta

    Sapienza University of Rome, Rome, Italy