H. Ying, Zhang Yu-jun, You Kun, Fan Bo-qiang, Ling Meng-Qi, Y. U. Dong-Qi, X. Hao, Lei Bo-En, Jia Wei, Jing Jun-Sen, Liu Wen-qing
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引用次数: 0
Abstract
The high-pressure absorption spectrum at 6046. 96 cm of methane was obtained with the measurement experimental platform. The empirical mode decomposition algorithm was used to filter out the detection noise caused by window deformation at high-pressure. Consequently,the overall root-mean-square error(RMSE)of absorbance signal was reduced by 3. 87 times,and the residual error of absorbance signal fitting was lower than ± 1% by using Lorentz line-type fitting algorithm. These studies showed that the absorption line width increased with the pressure increasing,and the mutual broadening coefficient of nitrogen-methane molecules at high-pres⁃ sure was calculated as 0. 0631 cm atm . Moreover,the absorption line appeared a "red shift" phenomenon as the pressure increasing,and the pressure shift coefficient of nitrogen-induced was calculated as -0. 00848 cm atm . Therefore,a method of concentration inversion at high pressure was proposed by the linear relationship between the detection wavelength,pressure,and pressure shift coefficient. In conclusion,the research on spectrum broad⁃ ening characteristics in high-pressure environment lays foundation for spectrum detecting in industrial environ⁃ ment.
高压吸收光谱在6046。测量实验平台得到了96 cm的甲烷。采用经验模态分解算法滤除高压下窗口变形引起的检测噪声。因此,吸光度信号的总体均方根误差(RMSE)减小了3。采用Lorentz线型拟合算法对吸光度信号拟合的残差小于±1%。这些研究表明,吸收谱线宽度随着压力的增加而增加,氮-甲烷分子在高压下的互展宽系数计算为0。0631厘米ATM。随着压力的增加,吸收谱线出现“红移”现象,计算出氮诱导的压力移系数为-0。00848 cm ATM。因此,提出了一种利用检测波长、压力和压力位移系数之间的线性关系反演高压下浓度的方法。总之,高压环境下频谱增宽特性的研究为工业环境下的频谱检测奠定了基础。
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