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24℃和0.1~900 MPa压力下乙醇的拉曼光谱研究 被引量:5

The Study of Raman Spectra for Ethanol under the Pressures of 0.1-900 MPa at 24 ℃
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摘要 在24 ℃和0.1~900 MPa压力下测量了含50%水的乙醇溶液和纯乙醇的激光拉曼光谱. 研究结果表明, 纯乙醇和50%乙醇溶液中的C-H基团振动波数均随压力的增大而增大, 它们的各振动峰与压力的关系分别为: 纯乙醇: ν1=2 881.890+0.001 27 P+6.213×10-6 P2;ν2=2 928.707+0.004 38 P+4.772×10-6 P2;ν3=2 973.457+0.008 89 P+3.245×10-6 P2;50%乙醇溶液: ν1 =2 885.616+0.010 8 P-2.699×10-6 P2;ν2 =2 932.734+0.013 7 P-3.346×10-6 P2;ν3 =2 978.115+0.016 5 P-4.914×10-6 P2. 另外, 还观察到在低于550 MPa压力范围, 50%乙醇溶液中的氢键强度随压力的增大而明显增加, 550 MPa以上压力时不再随压力而发生变化. Experimental measurement and study of Raman spectra for pure ethanol and 50% ethanol aqueous solution has been conducted at ambient temperature and the pressures of 0.1-900 MPa by using Cubic Zirconia anvil cell. The result shows that the frequency of C--H stretch vibration increases with increasing pressure and each of their relation between the frequency and pressure can be expressed as following: for pure ethanol: v1 = 2 881. 890 + 0. 001 27 P + 6. 213 × 10^-6 P2 ; v2 = 2 928.707 + 0.004 38 P + 4.772 × 10^-6 P2 ; v3 = 2973.457 + 0. 008 89 P + 3.245 × 10^-6 P2 ; for 50% ethanol aqueous solution: v1 = 2 885.616 + 0. 010 8 P - 2.699× 10^-6 P2 ; v2 =2 932.734+0.013 7 P-3.346× 10^-6 P2 ; v3 =2 978.115+0.016 5 P-4.914× 10^-6 P2. Furthermore, the authors have observed that at the pressure lower than 550 MPa, the strength of hydrogen bonding becomes stronger with increasing pressure.
出处 《光谱学与光谱分析》 SCIE EI CAS CSCD 北大核心 2005年第8期1257-1261,共5页 Spectroscopy and Spectral Analysis
基金 国家自然科学基金(10299040 40173019)资助项目
关键词 高压 乙醇 拉曼位移 氢键 High pressure Alcohol, Raman shift Hydrogen bonding
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  • 1赵怀杰.白酒催陈中的可逆现象[J].酿酒科技,1995(1):28-29. 被引量:4
  • 2王夺元.-[J].波谱学杂志,1987,4(1):1-5.
  • 3Barnett J D,Block S,Piermarini G J. An Optical Fluorescence System for Quantitative Pressure Measurement in the Diamond-Anvil Cell [J]. Review of Scientific Instruments, 1973,44 : 1 -9.
  • 4Mao H K, Xu J, Bell P M. Calibration of the Ruby Pressure Gauge to 800 kbar under Quasi-Hydrostatic Conditions[J]. Journal of Geophysical Research, 1986,91 (B5) :4673-4676.
  • 5Bassett W A,Shen A H,Bucknum M. A New Diamond Cell for Hydrothermal Studies to 2.5 GPa and from --190℃ to 1200 ℃ [J]. Rev Sci Instrum,1994,64(8):2340.
  • 6Christian S, Martin A Z. In-Situ Raman Spectroscopy of Quartz: A Pressure Sensor for Hydrothermal Diamond-Anvil Cell Experiments at Elevated Temperatures [J]. American Mineralogist,2000,85:1725-1734.
  • 7Mao H K,Bell P M,Shaner J W,et al. Specific Volume Measurements of Cu,Mo,Pd and Ag and Calibration of the Ruby Fluorescence Pressure Gauge from 0.06 to 1 Mbar [J]. J Appl Phys, 1978,49:3276-3283.
  • 8Holloway J R. Fugacity and Activity of Molecular Species in Supercritical Fluids [A]. Fraser D G. Thermodynamics in Geology [C]. Dordrecht-Holland & Reidel Publishing Co, 1977,161 - 181.
  • 9Haar L,Gallagher J S, Kell G S. NBS/NRC Steam Tables:Thermodynamic and Transport Properties and Computer Programs for Vapor and Liquid States of Water,in SI Units [M]. Washington,DC: Hemisphere Publishing Comp,1984. 320.
  • 10Belonoshko A, Saxena S K. A Molecular Dynamics Study of the Pressure-Volume-Temperature Properties of Super-Critical Fluids 1. H20 [J]. Geochim Cosmochim, Acta, 1991,55:381 - 387.

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