端视电感耦合等离子体原子发射光谱中易电离元素引起的非光谱干扰,常使分析结果产生偏差。
The non-spectroscopic interference of easily ionized elements (EIEs) in axial inductively coupled plasma-atomic emission spectroscopy often makes the results deviate.
然后我们再开始讲元素周期表,我们会看到很多周期性规律,比如电离能,电子亲和能,电负性以及原子半径。
We'll then take a turn to talking about the periodic table, we'll look at a bunch of periodic trends, including ionization energy, electron affinity, electronegativity and atomic radius.
如果我们查阅图表,一级电离能,已经在元素周期表上标示了。
Well, if we look on the chart, the first ionization energy is what is reported in your Periodic Table.
利用元素分析、红外光谱、核磁共振氢谱和激光解析电离飞行时间质谱确证了其组成和结构。
Their chemical structures were confirmed by means of elemental analysis, infared spectra, proton nuclear magnetic resonance spectra and mass spectra.
具体地说,我们这里要问的是,从周期表来看,你认为,哪一个元素的电离能更低。
So specifically, what we're asking here is as we go across the periodic table, we want to consider which has the smaller ionization energy.
重元素高电离的离子特性对研究激光核聚变和X射线激光等领域都很重要。
The characteristics of the high Z ions are very important to the study of X ray lasing and other field.
计算了原子序数13至23的元素高电荷态离子基态电离能,计算结果与文献可提供的实验数据相符合。
The ionization energy of ground state of highly charged ions whose atomic number is between 13and 23 is calculated, and the results is consistent with experimental data of the literature.
计算了原子序数13至23的元素高电荷态离子基态电离能,计算结果与文献可提供的实验数据相符合。
The ionization energy of ground state of highly charged ions whose atomic number is between 13and 23 is calculated, and the results is consistent with experimental data of the literature.
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