微波消解顺序注射冷蒸汽原子荧光光谱法测定沉积物中的痕量汞

提出采用密闭微波消解结合顺序注射冷蒸汽原子荧光光谱法快速测定沉积物中痕量汞的新方法。利用10%HCl-50%HNO3-40%H2O和30%HCl-20%HNO3-50%H2O两种消解体系在140℃条件下消解5min,沉积物样品消解完全,且样品消解过程中痕量汞无损失。优化条件下,线性范围0.02～30ng.mL-1,检出限为0.5ng.g-1,RSD为3.7%(n=10)。标准参考物质GSD-2,GSD-9及GSD-10的测定值与推荐值吻合,实际样品加标回收率(91.2±4.3)%～(96.5±4.6)%。本法试剂用量少,快速准确,灵敏度高,线性范围宽,适合沉积物中的痕量汞的测定,有很好的实用价值。     

HgCdTe探测器Pt电阻测温分析

研究了PV型HgCdTe探测器在1.319 μm连续激光辐照下的温升效应。根据探测器的分层结构及测温Pt电阻的位置(冷面上),推断Pt电阻测得的温度并不直接反映HgCdTe芯片的温度,而是比芯片温度低很多。实验测量了Pt电阻的温升,数值模拟了Pt电阻温度随时间的变化以及探测器各层结构的温升情况,理论分析结果与实验结果相一致。     

Sensitivity comparison of gas chromatography–mass spectrometry with Cold EI and standard EI

Gas chromatography–mass spectrometry (GC–MS) with Cold EI is based on interfacing GC and MS with supersonic molecular beams (SMBs) along with electron ionization of vibrationally cold sample compounds in SMB in a fly-through ion source (hence the name Cold EI). Cold EI improves all the central performance aspects of GC–MS, and in this paper, we focus on its improvement of signal-to-noise ratio (S/N) and limits of detection (LODs). We found that the harder the compound for analysis with standard EI, the greater the Cold EI gain in S/N and LOD. The lower LOD and higher S/N of Cold EI emerge from a few reasons: (a) similar ionization yield as standard EI, (b) enhanced abundance of molecular ions, (c) elimination of vacuum background noise, (d) elimination of ion source-related peak tailing and degradation, (e) ability to lower the elution temperatures via the use of high column flow rates, and (f) greater range of thermally labile and low-volatility compounds that can be analyzed. We demonstrate the superior S/N and lower LOD of Cold EI versus standard EI in a range of compounds, from the simple-to-analyze octafluoronaphthalene all the way to reserpine and an organo-metallic compound that cannot be analyzed by standard EI. These compounds include methyl stearate, cholesterol, n-C₃₂H₆₆, large polycyclic aromatic hydrocarbons, dioctyl phthalates, diundecyl phthalate, pentachlorophenol, benzidine, lambda-cyhalothrin, and methidathion. The significantly lower Cold EI LODs that can be over 1000 times better than in standard EI further result in far superior response linearity and greater measurement dynamic range.