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采用电感耦合等离子体发射光谱法测定化肥中铊的含量,通过对测量过程进行分析,确定了不确定度的来源主要有电子天平、标准工作溶液配制、标准工作曲线拟合、样品消解液定容、消解回收率及测量重复性等引入的不确定度分量,其中样品处理消解回收率对不确定度的贡献最大。通过建立数学模型,对各不确定度分量进行评估量化,得到了测定结果的合成不确定度和扩展不确定度。结果显示,当置信概率为95%、包含因子为2时,样品中铊质量分数为0.316 mg/kg,其扩展不确定度为0.017 mg/kg。 相似文献
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Direct transition of potential of water droplets to electric energy using aligned single-walled carbon nanotubes 下载免费PDF全文
In this paper, we report that an electromotive force (EMF)
can be induced in a rope of aligned single-walled carbon nanotubes
(SWNTs) when water droplets fall on this rope. The magnitude of this
EMF depends sensitively on the slant angle of the SWNTs. Most
interestingly, both the magnitude and the direction of the induced
EFM can be modulated by applying a current to the SWNTs. The
concepts of electrical slip and no-slip are proposed and can be
quantitatively described by ``electrical slip resistance'. This
kind of generator does not need any magnet, rotor, {etc} and shows
quite a different operating mechanism and design compared with a
conventional large scale hydroelectric power generator. 相似文献
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为研究泡沫铜孔隙密度和H2体积分数对合成气爆炸特性的影响,在封闭的管道中安装了孔隙密度为15、25和40 ppi的泡沫铜,实验分析了当量比为1的合成气-空气在不同H2体积分数时的火焰结构、尖端速度和超压等参数变化规律。实验结果表明:火焰在泡沫铜上游的行为是受“郁金香”火焰形成过程的影响,泡沫铜对其没有影响。但是孔隙密度和H2体积分数的改变不仅会影响“郁金香”火焰的形成时间,还会影响变形“郁金香”火焰的形成。泡沫铜将火焰分割促使其从层流向湍流转化,对爆炸火焰传播起到加速作用。泡沫铜会引起管道内超压和火焰尖端速度的极大提升,且孔隙密度越小,H2体积分数越大,火焰穿过泡沫铜后的最大火焰尖端速度越大,压力上升幅度越大,超压峰值越高。
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Zn杂质扩散诱导AlGaInP/GaInP量子阱混杂 总被引:1,自引:0,他引:1
杂质扩散诱导量子阱混杂技术可用于制作腔面非吸收窗口,提高大功率半导体激光器的输出功率.以Zn2As2为扩散源,采用闭管扩散方式,在550℃下对650 nm半导体激光器的外延片进行了一系列Zn杂质扩散诱导量子阱混杂的实验.实验发现,随着扩散时间从20~120 min,样品光致发光(PL)谱蓝移偏移增加,峰值波长蓝移53 nm;当扩散时间超过60 min后,样品的PL谱中不仅出现了常见的蓝移峰,同时还出现了红移峰,峰值波长红移32 nm.分析表明PL谱蓝移来自Zn扩散引起的AlGaInP/GaInP间的量子阱混杂;红移来自Zn杂质扩散对样品中Ga0.51In0.49P缓冲层的影响.还研究了扩散温度(550℃)和扩散时间对样品晶体品质的影响,并在理论上计算了AlGaInP/GaInP量子阱混杂巾的Al-Ga的互扩散系数. 相似文献
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Performance of optical amplifier employing silica host magnesium-aluminum-germanium co-doped erbium-doped fiber 总被引:1,自引:0,他引:1
Two silica host magnesium(Mg)-aluminum(Al)-germanium(Ge) co-doped erbium-doped fibers (EDFs) have been fabricated, which have different Mg concentrations. The concentration of all the compositions in the preform is measured through electronics probe micro analysis (EPMA). The maximum Mg concentrations of fibers A and B are 3.98 and 1.28 mol%, respectively. The performance characteristics including absorption spectrum and gain are measured and analyzed. The absorption coefficients of fibers A and B are 13.3 and 14.3 dB/m respectively at wavelength of 1532 nm. The max gains of these two erbium-doped fiber amplifiers (EDFAs) are 30.1 and 35.9 dB with input signal power of -30 dBm and pump power of 100 mW at 980 nm. Fiber B with maximum Mg concentration 1.28 mol% has better performance than fiber A. Fiber B has high absorption coefficient and high gain characteristics. The optimum fiber B length of C-band EDFA is 7 m and that of L-Band EDFA is about 30 m, which is much shorter than standard commercial EDFAs. 相似文献
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