Your search keyword '"E.E. Mukhin"' showing total 3 results

1. ITER perspective on fusion reactor diagnostics—A spectroscopic view

Author

R. Hutton, Victor Udintsev, C. Vorpahl, M. De Bock, P. Maquet, E.E. Mukhin, B. Brichard, C. R. Seon, S. Pak, R. Reichle, G. Vayakis, I.M. Bukreev, Luciano Bertalot, F. Le Guern, J. M. Drevon, A.G. Razdobarin, Frank Leipold, Robin Barnsley, Laurent Marot, H.G. Lee, Fabien Seyvet, A. Mokeev, S. Simrock, M. Bassan, V. Martin, Philippe Mertens, L. Moser, and M. Ivantsivskiy

Subjects

010302 applied physics, Physics, Iter tokamak, Fusion power, 01 natural sciences, 010305 fluids & plasmas, visual_art, Temporal resolution, 0103 physical sciences, Electronic component, Systems engineering, visual_art.visual_art_medium, ddc:610, Atomic physics, Instrumentation, Mathematical Physics, High dynamic range

Abstract

The ITER tokamak requires diagnostics that on the one hand have a high sensitivity, high spatial and temporal resolution and a high dynamic range, while on the other hand are robust enough to survive in a harsh environment.In recent years significant progress has been made in addressing critical challenges to the development of spectroscopic (but also other) diagnostics. This contribution presents an overview of recent achievements in 4 topical areas:• First mirror protection and cleaning• Nuclear confinement• Radiation mitigation strategy for optical and electronic components• Calibration strategies

Published

2016

2. Thomson scattering diagnostic systems in ITER

Author

G. S. Kurskiev, E.E. Mukhin, Philip Andrew, M. Bassan, E. Yatsuka, Takaki Hatae, G. Vayakis, and Michael Walsh

Subjects

Physics, Electron density, Toroid, Thomson scattering, Divertor, Electron, Radius, Neutron radiation, 01 natural sciences, 010305 fluids & plasmas, Computational physics, 0103 physical sciences, Electron temperature, Atomic physics, 010306 general physics, Instrumentation, Mathematical Physics

Abstract

Thomson scattering (TS) is a proven diagnostic technique that will be implemented in ITER in three independent systems. The Edge TS will measure electron temperature Te and electron density ne profiles at high resolution in the region with r/a>0.8 (with a the minor radius). The Core TS will cover the region r/a

Published

2016

3. The ITER divertor Thomson scattering system: engineering and advanced hardware solutions

Author

M.M. Kochergin, A F Kornev, P.V. Chernakov, A.G. Razdobarin, A.S. Kukushkin, A. I. Borovkov, G N Baranov, K. A. Podushnikova, E.E. Mukhin, A S Voinov, V.S. Modestov, Anatoly Borisov, Philip Andrew, A. Encheva, A F Makushina, S.V. Masyukevich, A A Berezutsky, V. K. Stupnikov, Alexander Nemov, G. S. Kurskiev, S Yu Tolstyakov, Vladimir V. Semenov, A.N. Koval, and B A Yelizarov

Subjects

Operability, Materials science, business.industry, Stray light, Thomson scattering, Divertor, Detector, Grating, Laser, law.invention, Polychromator, Optics, law, business, Instrumentation, Mathematical Physics

Abstract

A divertor Thomson scattering (TS) system being developed for ITER has incorporated proven solutions from currently available TS systems. On the other hand any ITER diagnostic has to operate in a hostile environment and very restricted access geometry. Therefore the operation in an environment of intensive stray light, plasma background radiation, the necessity meet the requirement using only a 20 mm gap between divertor cassettes for plasma diagnosis as well as to measure plasma temperatures as low as 1 eV severely constrain the divertor TS diagnostic design. The challenging solutions of this novel diagnostic system which has to ensure its steady performance and also the operability and maintenance are the focus of this report. One of the most demanding parts of the in-vessel diagnostic equipment development is the design assessment using different engineering analyses. The task definition and first results of thermal, e/m and seismic analyses are provided. The process of further improving of the design involves identification of susceptible areas and multiple iterations of the design, as needed. One of the key points for all Thomson scattering diagnostics are the laser capabilities. A high-performance and high-power laser system using a steady-state and high-repetitive mode Nd:YAG laser (2J, 50–100Hz, 3ns) has been developed. The reduced laser pulse duration matched with high-speed low-noise APD detector can be very important under high background light level. For diagnostics such as Thomson scattering and Raman spectroscopy, a high-degree of discrimination against stray light at the laser wavelength is required for successful detection of wavelength-shifted light from the laser-plasma interaction region. For this case of high stray light level, a triple grating polychromator characterized by high rejection and high transmission has been designed and developed. The novel polychromator design minimizes stray light while still maintaining a relatively high transmission.

Published

2012