MeV-range velocity-space tomography from gamma-ray and neutron emission spectrometry measurements at JET

M Salewski,J Eriksson,M Nocente,G Gorini,J Madsen,M Schneider,T Koskela,D Moseev,C Hellesen,M Stejner,F Leipold,T Kurki-Suonio,Göran Ericsson ,Jesper Rasmussen ,A S Jacobsen ,S E Sharapov ,Anders Hjalmarsson ,Carlo Cazzaniga ,V Kiptily ,S K Nielsen ,S B Korsholm ,Federico Binda ,M Tardocchi

doi:10.1088/1741-4326/aa60e9

MeV-range velocity-space tomography from gamma-ray and neutron emission spectrometry measurements at JET

M Salewski, J Eriksson + Show 21 more

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https://doi.org/10.1088/1741-4326/aa60e9

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Journal: Nuclear Fusion	Publication Date: Mar 14, 2017
Citations: 56	License type: iop-standard

Affiliation: Technical University of Denmark, Uppsala University, Institute of Plasma Physics, University of Milano-Bicocca, ITER, Aalto University, Lawrence Berkeley National Laboratory, National Energy Research Scientific Computing Center, Max Planck Institute for Plasma Physics - Greifswald, Max Planck Institute for Plasma Physics, Culham Science Centre, Science and Technology Facilities Council, Rutherford Appleton Laboratory

#Harmonic Ion Cyclotron Resonance Heating #Velocity-space Tomography + Show 8 more

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Abstract

We demonstrate the measurement of a 2D MeV-range ion velocity distribution function by velocity-space tomography at JET. Deuterium ions were accelerated into the MeV-range by third harmonic ion cyclotron resonance heating. We made measurements with three neutron emission spectrometers and a high-resolution γ-ray spectrometer detecting the γ-rays released in two reactions. The tomographic inversion based on these five spectra is in excellent agreement with numerical simulations with the ASCOT–RFOF and the SPOT–RFOF codes. The length of the measured fast-ion tail corroborates the prediction that very few particles are accelerated above 2 MeV due to the weak wave-particle interaction at higher energies.

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