Your search keyword '"Chantant, M."' showing total 2 results

1. Determination of the mean energy of fast electron losses and anisotropies through thick-target emission on WEST.

Author

Barbui, T., Delgado-Aparicio, L.F., Stratton, B., Chellaï, O., Dumont, R., Hill, K.W., Pablant, N.A., and Savoye-Peysson, Y.

Subjects

ELECTRONS, ELECTRON energy loss spectroscopy, HARD X-rays, ENTHALPY, ELECTRON beams, HEAT flux, PLASMA boundary layers

Abstract

A new method to obtain the mean energy of fast electron losses in fusion plasmas using a versatile multi-energy hard x-ray (HXR) detector is presented. The method is based on measuring the thick-target emission of tungsten in the divertor region produced by fast electron losses interacting with the target and modeling the tungsten spectra by a Monte Carlo code which simulates the interaction between a beam of electrons and a solid target. The mean energy of the fast electron losses is determined through the comparison between the experimental and synthetic emission. The results show that fast electron losses during lower hybrid current drive discharges at WEST have a mean energy of 90–140 keV and represent only 2% of the total heat flux at the target. Additionally, anisotropic HXR emission has been detected for the first time at the WEST core and edge plasma, with opposite directions. It is due to the forward-peak emission of two distinctive populations of fast electrons: co-current fast electrons in the core and counter-current fast electron losses at the inner strike point. In view of future experiments like ITER where electron cyclotron current drive will generate a fast electron population, this technique could serve as a real-time monitor of fast electron losses and eventually feed an actuator on the current drive generation. [ABSTRACT FROM AUTHOR]

Published

2024

2. Fusion Energy Technology R&D Priorities

Author

Laila El-Guebaly and Laila El-Guebaly

Subjects

Nuclear fusion, Nuclear engineering, Nuclear energy

Abstract

Fusion Energy Technology R&D Priorities examines the current landscape of fusion technology. With a strong focus on technological advances, the book considers technical challenges and priorities to further the development of fusion research. Beginning with an introduction to fusion technology research and development, the book then presents an overview of basic magnetic fusion concepts, experimental facilities, and fusion materials R&D. Subsequent chapters then take a deep dive into capabilities of potential neutron sources for materials testing, plasma facing components, and blanket and tritium systems. Vacuum vessels and shields, and superconducting magnets are also highlighted, before concluding with modelling techniques, computational tools, safety features, and environmental considerations. Presenting the most advanced developments in nuclear fusion R&D, this is an essential read for researchers and engineers interested in nuclear energy and fusion technology. - Presents the latest advances and developments in fusion science and technology - Outlines the R&D priorities and critical issues that are foundational to the further development of fusion energy technologies - Identifies technical fusion challenges and considers future perspectives - Reviews the present-day status of essential R&D programs that support fusion for energy

Published

2024