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固态和液态钢的激光诱导等离子体比较 被引量:3

Comparison between the plasmas induced by laser on solid and molten steels
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摘要 比较了产生于室温固态钢以及高温液态钢上激光诱导等离子体的特征、原子铁的激发温度以及电子密度。通过在386~400nm波长范围的中性铁原子发射谱线,由波尔兹曼作图法确定了铁原子的激发温度。通过测量Al I394.4nm的谱线宽度,估算了电子密度。对固体钢来说,铁元素的激发温度从延迟时间为10μs时的10 800K下降到延迟时间为80μs时的7 300K。当延迟时间分别为10μs和70μs时,产生于固态钢和液态钢上等离子体间的激发温度并没有显著差别。在铁元素和铝元素大部分的中性原子线中,可以观察到液态钢的谱线宽度比固态钢的谱线宽度更窄。当激光脉冲的观察延迟时间均为10μs时,产生于液态钢上等离子体的电子密度大约为(0.99±0.15)×1017/cm3,这相当于产生在固态钢上等离子体电子密度的46%。 Plasma characteristics, excitation temperatures of atomic iron and electron densities, were compared between the laser-induced plasmas generated on solid steel at room temperature and molten steel. The excitation temperatures of iron atom were determined by Boltzmann plot using neutral iron atomic emission lines in the wavelength range of 386 to 400 nm. Electron densities were estimated by measured linewidths of A1 I 394.4 nm. Excitation temperature of iron decreased from 10 800 K at 10 μs to 7 300 K at 80μs of delays for solid steel. Excitation temperatures were not distinguishable between the plasmas generated on solid and molten steels at delays of 10 and 70 μs, respectively. The linewidths observed with molten steel were narrower than those observed with solid steel in most of neutral atomic lines of iron and aluminum. Electron density in the plasma produced on molten steel was estimated to be (0. 99~0.15) × 10^17 cm^-3 , which was 46% of electron density in the plasma on solid steel at the same observation delay of 10μs from the laser pulse.
作者 KONDO Hiroyuki
机构地区 新日本制铁株式会社高级技术实验室
出处 《冶金分析》 CAS CSCD 北大核心 2013年第5期1-5,共5页 Metallurgical Analysis
关键词 激光诱导击穿光谱(LIBS) 等离子体温度 电子密度 laser-induced breakdown spectroscopy(LIBS) plasma temperature electron density
分类号 TG142.1 [金属学及工艺—金属材料]
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参考文献21

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冶金分析
2013年 第5期

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