Physics design of the in-vessel collection optics for the ITER electron cyclotron emission diagnostic

W. L. Rowan; S. Houshmandyar; P. E. Phillips; M. E. Austin; J. H. Beno; A. E. Hubbard; A. Khodak; A. Ouroua; G. Taylor

doi:10.1063/1.4960420

Physics design of the in-vessel collection optics for the ITER electron cyclotron emission diagnostic

W. L. Rowan, S. Houshmandyar, P. E. Phillips, M. E. Austin, J. H. Beno, A. E. Hubbard, A. Khodak, A. Ouroua, G. Taylor

PPPL Engineering

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Abstract

Measurement of the electron cyclotron emission (ECE) is one of the primary diagnostics for electron temperature in ITER. In-vessel, in-vacuum, and quasi-optical antennas capture sufficient ECE to achieve large signal to noise with microsecond temporal resolution and high spatial resolution while maintaining polarization fidelity. Two similar systems are required. One views the plasma radially. The other is an oblique view. Both views can be used to measure the electron temperature, while the oblique is also sensitive to non-thermal distortion in the bulk electron distribution. The in-vacuum optics for both systems are subject to degradation as they have a direct view of the ITER plasma and will not be accessible for cleaning or replacement for extended periods. Blackbody radiation sources are provided for in situ calibration.

Original language	English (US)
Article number	11E132
Journal	Review of Scientific Instruments
Volume	87
Issue number	11
DOIs	https://doi.org/10.1063/1.4960420
State	Published - Nov 1 2016

All Science Journal Classification (ASJC) codes

Instrumentation

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title = "Physics design of the in-vessel collection optics for the ITER electron cyclotron emission diagnostic",

abstract = "Measurement of the electron cyclotron emission (ECE) is one of the primary diagnostics for electron temperature in ITER. In-vessel, in-vacuum, and quasi-optical antennas capture sufficient ECE to achieve large signal to noise with microsecond temporal resolution and high spatial resolution while maintaining polarization fidelity. Two similar systems are required. One views the plasma radially. The other is an oblique view. Both views can be used to measure the electron temperature, while the oblique is also sensitive to non-thermal distortion in the bulk electron distribution. The in-vacuum optics for both systems are subject to degradation as they have a direct view of the ITER plasma and will not be accessible for cleaning or replacement for extended periods. Blackbody radiation sources are provided for in situ calibration.",

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doi = "10.1063/1.4960420",

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T1 - Physics design of the in-vessel collection optics for the ITER electron cyclotron emission diagnostic

AU - Rowan, W. L.

AU - Houshmandyar, S.

AU - Phillips, P. E.

AU - Austin, M. E.

AU - Beno, J. H.

AU - Hubbard, A. E.

AU - Khodak, A.

AU - Ouroua, A.

AU - Taylor, G.

PY - 2016/11/1

Y1 - 2016/11/1

N2 - Measurement of the electron cyclotron emission (ECE) is one of the primary diagnostics for electron temperature in ITER. In-vessel, in-vacuum, and quasi-optical antennas capture sufficient ECE to achieve large signal to noise with microsecond temporal resolution and high spatial resolution while maintaining polarization fidelity. Two similar systems are required. One views the plasma radially. The other is an oblique view. Both views can be used to measure the electron temperature, while the oblique is also sensitive to non-thermal distortion in the bulk electron distribution. The in-vacuum optics for both systems are subject to degradation as they have a direct view of the ITER plasma and will not be accessible for cleaning or replacement for extended periods. Blackbody radiation sources are provided for in situ calibration.

AB - Measurement of the electron cyclotron emission (ECE) is one of the primary diagnostics for electron temperature in ITER. In-vessel, in-vacuum, and quasi-optical antennas capture sufficient ECE to achieve large signal to noise with microsecond temporal resolution and high spatial resolution while maintaining polarization fidelity. Two similar systems are required. One views the plasma radially. The other is an oblique view. Both views can be used to measure the electron temperature, while the oblique is also sensitive to non-thermal distortion in the bulk electron distribution. The in-vacuum optics for both systems are subject to degradation as they have a direct view of the ITER plasma and will not be accessible for cleaning or replacement for extended periods. Blackbody radiation sources are provided for in situ calibration.

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JF - Review of Scientific Instruments

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Physics design of the in-vessel collection optics for the ITER electron cyclotron emission diagnostic

Abstract

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