方法采用免疫组化法及凝胶电泳迁移率实验。
Methods Immunohistochemistry and electrophoretic mobility shift assay (EMSA) were used.
与实验比较,给出了隙态分布的位置、宽度和高度,也给出了电子迁移率和复合系数。
Compared with the experimental results, the position, width and peak of distribution of states in gap, and also the electron mobility, cross section ot capture are obtained.
为了提高计算的正确性,提出应进行深入的少子迁移率测量研究,以能为计算提供系统的、可靠的实验数据。
However, for increasing calculation correctness some studies on minority mobility measurements are needed to offer systematic and reliable experimental data.
考虑室内实验与野外自然环境之间存在的尺度效应,合理确定了阻滞因子、水化学迁移率。
The scale effect has been considered between indoor experiments and natural environment to determine the retardation factor and the hydrochemical mobility properly.
通过霍尔效应实验测定的霍尔系数,能够判断半导体材料的导电类型、载流子浓度及载流子迁移率等重要参数。
The coefficient of Hall-effect decided by experiment can determine the type of semiconductor materials, the concentration of carrier, the mobility of carrier and other important parameters.
通过霍尔效应实验测定的霍尔系数,能够判断半导体材料的导电类型、载流子浓度及载流子迁移率等重要参数。
The coefficient of Hall-effect decided by experiment can determine the type of semiconductor materials, the concentration of carrier, the mobility of carrier and other important parameters.
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