Determination of the deuterium temperature profile in magnetic fusion plasmas

Gorini, G.; Gottardi, N.A.C.

doi:10.1007/bf02456960

Cited by 5 publications

(1 citation statement)

References 11 publications

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“…In principle, even the T~ profile can be derived from the emissivity data from the cameras as done in [42]. NS data in context of other diagnostics.…”

Section: -Spectrometers For 14 Mev Neutronsmentioning

confidence: 99%

Neutron spectrometry in compact ignition experiments

Gorini

Källne

1992

Il Nuovo Cimento D

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ricevuto il 5 Febbraio 1992; approvato il 22 Maggio 1992)Summary. --The role of neutron spectrometry is discussed as a diagnostics of plasmas of compact ignition experiments. The situation with regard to instrumentation (including diagnostic capabilities and limitations) is reviewed on the basis of existing experience and new solutions are proposed as required by compactplasma observations. Especially, the question of time resolution is addressed and a dedicated spectrometer system is devised to make use of the high neutron fluxes expected for the nuclear-burn phase of compact plasmas. It is shown that a system of three neutron spectrometers can provide adequate data on ion temperature of D and DT plasmas over a range of plasma conditions of interest and with the required accuracy. The diagnostic output from this neutron spectrometer system is presented especially with regard to flash ignition studies.PACS 52.70 -Plasma diagnostic techniques and instrumentation.

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“…In principle, even the T~ profile can be derived from the emissivity data from the cameras as done in [42]. NS data in context of other diagnostics.…”

Section: -Spectrometers For 14 Mev Neutronsmentioning

confidence: 99%

Neutron spectrometry in compact ignition experiments

Gorini

Källne

1992

Il Nuovo Cimento D

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Neutron emission spectrometer in magnetic confinement fusion

Sangaroon,

Ogawa,

Isobe

2024

AAPPS Bull.

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Comprehensive neutron diagnostics have been developed and used to study magnetic confinement fusion plasmas. The neutron emission spectrometer is one of the most powerful tools for understanding fusion plasma physics. Neutron spectroscopy was originally developed to measure the fuel ion temperature in thermal plasmas. With the advent of fast ion heating, the role of neutron spectroscopy has evolved to deepen the understanding of fast ion confinement. Since neutrons are primarily produced by the fusion reaction between the bulk ion and the fast ion, the neutron energy carries information about the fast ion energy. The details of neutron emission spectrometers, i.e., time-of-flight spectrometer, magnetic proton recoil spectrometer, and compact neutron emission spectrometer, as well as representative results of neutron spectrometry in Large Helical Device are reviewed.

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