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Collisional broadening of CO2 IR lines. II. Calculations (1988)

Rosenmann, L. ; Hartmann, J. M. ; Perrin, M. Y. ; [et al.]

College Park, Md. : American Institute of Physics (AIP)

The Journal of Chemical Physics 88 (1988), S. 2999-3006

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ISSN: 1089-7690

Source: AIP Digital Archive

Topics: Physics , Chemistry and Pharmacology

Notes: The ability of available theoretical models in describing broadening mechanisms is tested for the CO2–O2, CO2–CO2, and CO2–N2 systems. It is shown that the Anderson–Tsao–Curnutte theory is inaccurate since short-range forces can contribute significantly to broadening. We use the approach of Robert and Bonamy, but the usual expansion of the atom–atom potential to the fourth order around the intermolecular distance appears insufficient at short distances for these particular systems. We propose a better representation of the radial dependence of the atom–atom potential, while keeping the previous analytical expression of the cross section. Satisfactory results are obtained for both the rotational quantum number dependence of room-temperature CO2–O2, CO2–CO2, and CO2–N2 half-widths and the evolution of CO2–N2 broadening with temperature. It is shown that the isotropic part of the potential involved in the trajectory calculation must be coherently deduced from the atom–atom interaction potential.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1063/1.453941

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Study and design of the ion cyclotron resonance heating system for the stellarator Wendelstein 7-X (2014)

J. Ongena, A. Messiaen, D. Van Eester, B. Schweer, P. Dumortier, F. Durodie, Ye. O. Kazakov, F. Louche, M. Vervier, R. Koch, A. Krivska, A. Lyssoivan, M. Van Schoor, T. Wauters, V. Borsuk, O. Neubauer, O. Schmitz, G. Offermans, Y. Altenburg, C. Baylard, D. Birus, S. Bozhenkov, D. A. Hartmann, J. P. Kallmeyer, S. Renard, R. C. Wolf and T. Fülöp

American Institute of Physics (AIP)

In: Physics of Plasmas

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Publication Date: 2014-06-27

Description: The current status of the mechanical and electromagnetic design for the ICRF antenna system for W7-X is presented. Two antenna plugins are discussed: one consisting of a pair of straps with pre-matching to cover the first frequency band, 25–38 MHz, and a second one consisting of two short strap triplets to cover a frequency band around 76 MHz. This paper focusses on the two strap antenna for the lower frequency band. Power coupling of the antenna to a reference plasma profile is studied with the help of the codes TOPICA and Microwave Studio that deliver the scattering matrix needed for the optimization of the geometric parameters of the straps and antenna box. Radiation power spectra for different phasings of the two straps are obtained using the code ANTITER II and different heating scenario are discussed. The potential for heating, fast particle generation, and current drive is discussed. The problem of RF coupling through the plasma edge and of edge power deposition is summarized. Important elements of the complete ion cyclotron resonance heating system are discussed: a resonator circuit with tap feed to limit the maximum voltage in the system, and a decoupler to counterbalance the large mutual coupling between the 2 straps. The mechanical design highlights the challenges encountered with this antenna: adaptation to a large variety of plasma configurations, the limited space within the port to accommodate the necessary matching components and the watercooling needed for long pulse operation.

Print ISSN: 1070-664X

Electronic ISSN: 1089-7674

Topics: Physics

Published by American Institute of Physics (AIP)

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