Benefits and Challenges of the Use of High-Z Plasma Facing Materials in Fusion Devices

Neu, R.

doi:10.1063/1.3447994

Cited by 4 publications

(1 citation statement)

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“…The tungsten released from the divertor plate components and first wall can diffuse into the main plasma, leading to the degradation of its performance, and even cause it to disrupt. The high cooling factors of tungsten [27], resulting from its partial ionization within the confined plasma, remains significant even at temperatures relevant to a reactor, ranging from 10 to 20 keV [28]. For this reason, the new generation tokamak devices, characterized by metallic PFC, are now equipped with dedicated systems for the spectroscopic investigation of the tungsten distribution at the divertor region.…”

Section: Divertor Imaging Systemmentioning

confidence: 99%

Conceptual design of Visible Spectroscopy diagnostics for DTT

Belpane,

Carraro,

Fassina

et al. 2024

Plasma Phys. Control. Fusion

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The project of the Visible Spectroscopy diagnostics for the Zeff radial profile measurement and for the divertor visible imaging spectroscopy, designed for the new tokamak DTT (Divertor Tokamak Test), is presented. To deal with the geometrical constrains of DTT and to minimize the diagnostics volume inside the access port, an integrated and compact solution hosting the two systems has been proposed. The Zeff radial profile will be evaluated from the Bremsstrahlung radiation measurement in the visible spectral range, acquiring light along ten Lines of Sight (LoS) in the upper part of the poloidal plane. The plasma emission will be focused on optical fibers, which will carry it to the spectroscopy laboratory. A second equipment, with a single toroidal LoS crossing the plasma centre and laying on the equatorial plane, will measure the average Zeff on a longer path, minimizing the incidental continuum spectrum contaminations by lines/bands emitted from the plasma edge. The divertor imaging system is designed to measure impurity and main gas influxes, to monitor the plasma position and kinetics of impurities, and to follow the plasma detachment evolution. The project aims at obtaining the maximum coverage of the divertor region. The collected light can be shared among different spectrometers and interferential filter devices placed outside the torus hall to easily change their setup. The system is composed of two telescopes, an upper and a lower one, allowing both a perpendicular and a tangential view of the DTT divertor region. This diagnostic offers a unique and compact solution designed to cope, the demanding constraints of this next-generation tokamak fusion devices, integrating essential tools for wide-ranging impurity characterization and versatile invesitgation of divertor physics.

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Section: Divertor Imaging Systemmentioning

confidence: 99%