Physical Sciences Inc. Publications Abstract: The electric oxygen-iodine laser: Chemical kinetics of O2(a1Δ) production and I(2P1/2) excitation in microwave discharge systems

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Abstract: The electric oxygen-iodine laser: Chemical kinetics of O2(a1Δ) production and I(2P1/2) excitation in microwave discharge systems

W.T. Rawlins, S. Lee, W.J. Kessler, D.B. Oakes, L.G. Piper, S.J. Davis, "The electric oxygen-iodine laser: Chemical kinetics of O2(a1Δ) production and I(2P1/2) excitation in microwave discharge systems ," presented at LASE 2006 High Energy/Average Power Lasers and Intense Beam Applications (San Jose, CA) , (21-26 January2006).

This paper was published in LASE 2006 High Energy/Average Power Lasers and Intense Beam Applications, and is made available as an electronic reprint (preprint) with permission of SPIE. One print or electronic copy may be made for personal use only. Systematic or multiple reproduction, distribution to multiple locations via electronic or other means, duplication of any material in this paper for a fee or for commercial purposes, or modification of the content of the paper are prohibited.

Abstract

Generation of singlet oxygen metastables, O₂(a¹Δ), in an electric discharge plasma offers the potential for development of compact electric oxygen-iodine laser (EOIL) systems using a recyclable, all-gas-phase medium. The primary technical challenge for this concept is to develop a high-power, scalable electric discharge configuration that can produce high yields and flow rates of O₂ (a) to support I(² P_1/2 - ² P_3/2) lasing at high output power. This paper discusses the chemical kinetics of the generation of O₂ (a) and the excitation of I(² P_1/2) in discharge-flow reactors using microwave discharges at low power, 40-120 W, and moderate power, 1-2 kW. The relatively high E/N of the microwave discharge, coupled with the dilution of O₂ 2 with Ar and/or He, leads to increased O₂ (a) production rates, resulting in O₂ (a) yields in the range 20-40%. At elevated power, the optimum O₂ (a) yield occurs at higher total flow rates, resulting in O₂ (a) flow rates as large as 1 mmole/s (~100 W of O₂ (a) in the flow) for 1 kW discharge power. We perform the reacting flow measurements using a comprehensive suite of optical emission and absorption diagnostics to monitor the absolute concentrations of O₂ (a), O₂ (b), O(³P), I₂, I(² P_3/2), I(² P_1/2), small-signal gain, and temperature. These measurements constrain the kinetics model of the system, and reveal the existence of new chemical loss mechanisms related to atomic oxygen. The results for O₂ (a) production at 1 kW have intriguing implications for the scaling of EOIL systems to high power.

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