光谱学与光谱分析 |
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High Resolution Laser Transient Spectroscopic Technology under Two-Stage Light Gas-Gun Loading Condition and Stability Study of Shocked Benzene |
ZHAO Bei-jing, LIU Fu-sheng*, WANG Wen-peng, ZHANG Ning-chao, FENG Li-peng, ZHANG Ming-jian, XUE Xue-dong |
Laboratory of High Pressure Physics, Southwest Jiaotong University, Chengdu 610031, China |
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Abstract The present paper reports the high resolution transient Raman laser testing technology under two-stage light gas-gun loading experiment, and its application to studying the Raman spectroscopy of shocked benzene. In the experiments, the frequency shift of C—C stretching vibration (992 cm-1) and C—H stretching vibration peak (3 061 cm-1) in the low pressure section (less than 8 GPa) varies linearly with the pressure, and the results agree well with reported data in the literature. The structural changes in liquid benzene about 13 GPa were clarified firstly by the Raman spectral technique; the experimental results show that at a pressure of 9.7 GPa, the structural change of liquid benzene has taken place, not reported in the literature about 13 GPa. But the composition in the production is not clear. The measurement system provides an effective means to study the microstructure changes of transparent and translucent material under dynamic loading experiment.
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Received: 2012-12-14
Accepted: 2013-03-18
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Corresponding Authors:
LIU Fu-sheng
E-mail: fusheng_l@sohu.com
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