Transformation of nitrogen SPS spectra emitted from streamer discharge head within a sub-nanosecond — Nanosecond range

Y. Shcherbakov, L. Nekhamkin
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Abstract

The paper presents some results on spectroscopic studies of the filamentary streamer discharge in short air gap in stage of primary streamer propagation. Basically, we have found that the mid-resolved (with spectral resolution around 0.2-0.3 nm) nitrogen second positive system (SPS) spectra emitted from the primary streamer head changes essentially in form within some nanoseconds. Namely, main peak near the band head formed by the P-branches of Pi3-to-Pi3 transition turns almost into a widened twin-peak hump, relative intensities of each sub-peaks change in time resulting finally in a quite usual one-peak form; with inessential modification of short-wave part of the SPS-band as whole formed mainly by the R-branches. In attempt to give an appropriate realistic interpretation of this phenomenon we have analyzed different possible instrumental factors as well as mechanisms applied in streamer theory and molecular spectroscopy, such as: 1) dynamic breaking of the spin-axis coupling of the Pi3-states resulting in an appearance of Pi3(a)-to-Pi3(b)- and Pi3(b)-to-Pi3(b)-transitions additionally to a standard Pi3(a)-to-Pi3(a)-transition; 2) modeling of luminosity emitted from the actual high-gradient too narrow streamer head propagating with very high speed; 3) fast eventual heating of neutral gas within streamer head; 4) possible non-even illumination of the monochromator entrance slit due to very strong gradient of all physical parameters within streamer head and finally as well as actual sub-nanosecond temporal resolution of the measuring system; 5) Zeeman and Stark-effects. Stark-effect and instrumental peculiarities are supposed to be most adequate reasons for the phenomenon, which after development of relevant detailed theory might be applicable to determine/estimate electric field and its spatial gradient, respectively
流光放电头发射的氮SPS光谱在亚纳秒-纳秒范围内的转换
本文介绍了主流传播阶段短气隙中细丝流放电的光谱学研究结果。基本上,我们发现从主拖缆头发射的中分辨率(光谱分辨率约为0.2-0.3 nm)氮秒正系统(SPS)光谱在一些纳秒内基本上改变了形式。即,由pi3 - pi3过渡的p分支形成的带头附近的主峰几乎变成了一个加宽的双峰峰,各子峰的相对强度随时间变化,最终形成了一个非常常见的单峰形式;主要由r支路构成的sps波段的短波部分被不必要地修改。为了对这一现象给出适当的现实解释,我们分析了不同可能的仪器因素以及应用于流光理论和分子光谱学的机制,例如:1)Pi3态自旋轴耦合的动态断裂导致Pi3(a)到Pi3(b)-和Pi3(b)到Pi3(b)-的转变,而不是标准的Pi3(a)到Pi3(a)-转变;2)实际高梯度过窄流光头高速传播的光度建模;3)拖缆头内中性气体最终快速加热;4)由于流光头内所有物理参数的梯度非常强,最后以及测量系统的实际亚纳秒级时间分辨率,单色器入口狭缝可能出现非均匀照明;塞曼和斯塔克效应。stark效应和仪器特性被认为是造成这一现象的最充分的原因,在相关的详细理论发展之后,它们可能分别适用于确定/估计电场及其空间梯度
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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