Analyzing the energy spectra of ion beams emitted from neon Z-pinch plasma with a compact Thomson spectrometer.
使用紧凑式汤姆生离子谱仪测量Z箍缩氖气等离子体的辐射离子束能谱。
The emission spectra of he plasma were measured by using three types of experiment devices: dielectric barrier discharge device, hollow-cathode discharge device and Penning discharge device.
采用三种实验装置(介质阻挡放电装置、空心阴极放电装置和彭宁放电装置)分别测量了不同压强范围内氦等离子体的发射光谱。
The XUV spectra from Ag XIX of laser-produced plasma are measured.
测量了激光加热块状银靶产生的等离子体XUV光谱。
Furthermore, the plasma optical emission spectra (OES) of the ionization of the working gases were analyzed in situ using a PR-650 spectroscope.
此外,本文使用PR—650光谱光度计,对P室的等离子体辉光光谱(OES)进行了在线监测。
In this paper, a diagnostic method of average ionization degree by X-ray emission spectra of laser-produced gold plasma was presented.
提出一种测量金激光等离子体电荷态分布与平均电离度的X射线光谱学诊断方法。
The experimental results indicated that the fluorescence and RSS of plasma increased with concentration, but the spectra of whole blood and red blood cell first rose and then dropped.
红细胞和全血溶液则同时表现为先升高后降低,并且荧光光谱还出现了蓝移的现象。
A method to determine the electron temperature and density from the time resolved spectra of hydrogen atoms left in a pulsed laser plasma is described.
本文讨论了一种利用残留在激光器中杂质氢原子的时间分辨光谱,来确定脉冲激光等离子体电子温度和电子密度的方法。
By any of the above mentioned methods, a characteristic emission spectra can be obtained for the plasma gas and each substance in it.
通过前面的任何一种方式,可得到等离子气体和其它组分的特征发射光谱。通过特征光谱判定每种物质。
A 532 nm laser was used as exciting source to measure the fluorescence spectra of human blood and its components (red blood cell, blood platelet and blood plasma).
用532nm的激光作为激发光源,分别测量正常人血液及血液组分(血浆、血小板、红细胞)的荧光光谱。
A 532 nm laser was used as exciting source to measure the fluorescence spectra of human blood and its components (red blood cell, blood platelet and blood plasma).
用532nm的激光作为激发光源,分别测量正常人血液及血液组分(血浆、血小板、红细胞)的荧光光谱。
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