结论:拉曼光谱法快速、直接、对样品无损伤,是一种新的理想的检查固体分散体分散性的方法。
Conclusion: Raman spectrometry which is fast, direct and non-destructive is an ideal method in examining the dispersivity of solid dispersion.
结论:拉曼光谱法快速、直接、对样品无损伤,是一种新的理想的检查固体分散体分散性的方法。
Conclusion: Raman spectrometry which is fast, direct and non-destructive is an ideal method for examining the dispersivity of solid dispersion.
再应用微拉曼光谱法测量了热障涂层样品内残余应力场大小,并分析了试样尺寸、热处理温度和陶瓷涂层厚度对残余应力的影响。
The residual stress fields of thermal barrier ceramic coating were measured for every twenty thermal cycles by using micro-Raman spectroscopy technique.
沟道应力的模拟方法则采用掩膜版边缘错位模型(mask - edge dislocation model),应力测量方面采用拉曼光谱法。
Channel stress is simulated by using mask-edge dislocation model and actual stress is also measured by Raman spectroscopy.
利用扫描电子显微镜、拉曼光谱法和循环伏安法对这两种电极的表面形貌、单链dna在电极表面的自组装性能和其电化学行为进行了研究。
The surface modality of electrodes, and the self-assembling performance of single-strand DNA on the surface of electrodes were characterized with scanning electron microscope and Raman spectroscopy.
利用扫描电子显微镜、拉曼光谱法和循环伏安法对这两种电极的表面形貌、单链dna在电极表面的自组装性能和其电化学行为进行了研究。
The surface modality of electrodes, and the self-assembling performance of single-strand DNA on the surface of electrodes were characterized with scanning electron microscope and Raman spectroscopy.
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