| 光谱学与光谱分析 |
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| Review on Application of Optical Scattering Spectroscopy for Elastic Wave Velocity Study on Materials in Earth’s Interior |
| JIANG Jian-jun1,2, LI He-ping1*, DAI Li-dong1, HU Hai-ying1, WANG Yan1,2, ZHAO Chao-shuai1,2 |
1. Key Laboratory for High Temperature and High Pressure Study of the Earth’s Interior, Institute of Geochemistry, Chinese Academy of Sciences, Guiyang 550002, China
2. University of Chinese Academy of Sciences, Beijing 100049, China |
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Abstract In-situ experimental results on the elastic wave velocity of Earth materials at high pressure and high temperature in combination with data from seismic observation can help to inverse the chemical composition, state and migration of materials in Earth’s interior, providing an important approach to explore information of deep earth. Applying the Brillouin scattering into the Diamond Anvil Cell (DAC) to obtain the in situ elastic wave velocities of minerals, is the important approach to investigate elastic properties of Earth’s Interior. With the development of DAC technology, on the one hand, the high temperature and high pressure experimental environment to simulate different layers of the earth can be achieved; on the other hand, the optical properties of DAC made many kinds of optical analysis and test methods have been widely applied in this research field. In order to gain the elastic wave velocity under high temperature and high pressure, the accurate experimental pressure and heating temperature of the sample in the cavity should be measured and calibrated first, then the scattering signal needs to dealt with, using the Brillouin frequency shift to calculate the velocity in the sample. Combined with the lattice constants obtained from X ray technique, by a solid elastic theory, all the elastic parameters of minerals can be solved. In this paper, firstly, application of methods based on optical spectrum such as Brillouin and Raman scattering in elasticity study on materials in Earth’s interior, and the basic principle and research progress of them in the velocity measurement, pressure and temperature calibration are described in detail. Secondly, principle and scope of application of two common methods of spectral pressure calibration (fluorescence and Raman spectral pressure standard) are analyzed, in addition with introduce of the application of two conventional means of temperature calibration (blackbody radiation and Raman temperature scale) in temperature determination. Lastly, geophysical applications of mineral elasticity are discussed on the basis of the recent research results derive from Brillouin scattering system of wave velocities for major minerals in Earth’s lower mantle (perovskite, ferropericlase, etc. ), and the future research work is inspected.
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Received: 2014-06-30
Accepted: 2014-10-05
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Corresponding Authors:
LI He-ping
E-mail: liheping2014@hotmail.com
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[1] Schubert G. Treatise on Geophysics: Earthquake Seismology. Amsterdam: Elsevier Press, 2007.
[2] Chen J, Wang Y, Duffy S,et al. Advances in High-Pressure Techniques for Geophysical Applications. Amsterdam: Elsevier Press, 2011.
[3] Mueller H. Journal of Geodynamics, 2013, 71(9): 25.
[4] Li B, Kung J, Liebermann R. Physics of the Earth and Planetary Interiors, 2004, 143: 559.
[5] Li B, Zhang J. Physics of the Earth and Planetary Interiors, 2005, 151(1): 143.
[6] Angel R, Jackson J, Reichmann H,et al. European Journal of Mineralogy, 2009, 21(3): 525.
[7] Bassett W. High Pressure Research, 2009, 29(2): 163.
[8] Piermarini G. Static Compression of Energetic Materials. New York: Springer, 2008.
[9] LIU Chuan-jiang, ZHENG Hai-fei(刘川江, 郑海飞). Earth Science Frontiers(地学前缘), 2012, 19(4): 141.
[10] JIA Ru, CUI Qi-liang, LI Fang-fei, et al(贾 茹, 崔启良, 李芳菲, 等). The Journal of Light Scattering(光散射学报), 2008, 20(3): 212.
[11] Li F, Cui Q, He Z,et al. Applied Physics Letters, 2006, 88(20): 203507.
[12] Speziale S, Marquardt H, Duffy T. Reviews in Mineralogy and Geochemistry, 2014, 78(1): 543.
[13] ZHANG Ming-sheng(张明生). Laser Light Scattering Spectroscopy(激光光散射谱学). Beijing: Science Press(北京:科学出版社), 2008.
[14] CHENG Guang-xu(程光煦). Raman Brillouin Scattring(拉曼布里渊散射). Beijing: Science Press(北京:科学出版社), 2008.
[15] Sinogeikin S, Lakshtanov D, Nicholas J,et al. Journal of the European Ceramic Society, 2005, 25(8): 1313.
[16] Dai L, Kudo Y, Hirose K,et al. Physics and Chemistry of Minerals, 2013, 40(3): 195.
[17] ZHENG Hai-fei, SUN Qiang, ZHAO Jin, et al(郑海飞, 孙 樯, 赵 金, 等). Chinese Journal of High Pressure Physics(高压物理学报), 2004, 18(1): 78.
[18] Syassen K. High Pressure Research, 2008, 28(2): 75.
[19] Forman R, Piermarini G, Barnett J,et al. Science, 1972, 176(4032): 284.
[20] Piermarini G, Block S, Barnett J,et al. Journal of Applied Physics, 1975, 46(6): 2774.
[21] Mao H, Xu J, Bell P. Journal of Geophysical Research: Solid Earth, 1986, 91(B5): 4673.
[22] Chijioke A, Nellis W, Soldatov A,et al. Journal of Applied Physics, 2005, 98(11): 114905.
[23] Datchi F, Dewaele A, Loubeyre P,et al. High Pressure Research, 2007, 27(4): 447.
[24] Jing Q, Wu Q, Liu Y,et al. High Pressure Research, 2013, 33(4): 725.
[25] Schmidt C, Steele-MacInnis M, Watenphul A,et al. American Mineralogist, 2013, 98(4): 643.
[26] Goncharov A, Sinogeikin S, Crowhurst J,et al. High Pressure Research, 2007, 27(4): 409.
[27] Goncharov A, Crowhurst J, Dewhurst J,et al. Physical Review B, 2005, 72(10): 100104.
[28] Akahama Y, Kawamura H. Journal of Physics: Conference Series,2010, 215(1): 012195.
[29] Dubrovinskaia N, Dubrovinsky L, Caracas R,et al. Applied Physics Letters, 2010, 97(25): 251903.
[30] ZHENG Hai-fei(郑海飞). Experimental Techniques of DAC for High Temperature and Pressure Studies and Its Applications(金刚石压腔高温高压实验技术及其应用). Beijing: Science Press(北京:科学出版社), 2008.
[31] Zhuravlev K, Goncharov A, Tkachev S,et al. Journal of Applied Physics, 2013, 113(11): 113503.
[32] Zha C, Duffy T, Downs R,et al. Earth and Planetary Science Letters, 1998, 159(1): 25.
[33] Zha C, Mao H, Hemley R. Proceedings of the National Academy of Sciences, 2000, 97(25): 13494.
[34] Jackson J, Sinogeikin S, Bass J. American Mineralogist, 2000, 85(2): 296.
[35] Jackson J, Sinogeikin S, Bass J. Physics of the Earth and Planetary Interiors, 2007, 161(1): 1.
[36] Lu C, Mao Z, Lin J,et al. Earth and Planetary Science Letters, 2013, 361: 134.
[37] Sinogeikin S, Lakshtanov D, Nicholas J,et al. Physics of the Earth and Planetary Interiors, 2004, 143: 575.
[38] Lin J, Santoro M, Struzhkin V,et al. Review of Scientific Instruments, 2004, 75 (10): 3302.
[39] Lin J, Sturhahn W, Zhao J,et al. Geophysical Research Letters, 2004, 31(14): L14611.
[40] Santoro M, Lin J, Mao H,et al. The Journal of Chemical Physics, 2004, 121: 2780.
[41] Duffy T, Zha C, Downs R,et al. Nature, 1995, 378(6553): 170.
[42] Carpenter M, Hemley R, Mao H. Journal of Geophysical Research, 2000, 105(B5): 10807.
[43] Asahara Y, Hirose K, Ohishi Y,et al. American Mineralogist, 2013, 98(11-12): 2053.
[44] Zhang L, Chopelas A. Physics of the Earth and Planetary Interiors, 1994, 87(1): 77.
[45] Murakami M, Hirose K, Kawamura K,et al. Science, 2004, 304(5672): 855.
[46] Murakami M, Sinogeikin S, Bass J,et al. Earth and Planetary Science Letters, 2007, 259(1): 18.
[47] Murakami M, Sinogeikin S, Hellwig H,et al. Earth and Planetary Science Letters, 2007, 256(1): 47.
[48] Murakami M, Ohishi Y, Hirao N,et al. Earth and Planetary Science Letters, 2009, 277(1): 123.
[49] Kudo Y, Hirose K, Murakami M,et al. Earth and Planetary Science Letters, 2012, 349: 1.
[50] Auld B. Acoustic Fields and Waves in Solids. New York: Wiley USA, 1973.
[51] Musgrave M. J. Crystal Acoustics. San Francisco: Holden-Day USA, 1970.
[52] WANG Yan, LI He-ping, WANG Pan(王 燕, 李和平, 王 攀). Acta Mieralogica Sinica(矿物学报), 2014, 34(2): 283.
[53] Ringwood A. Origin of earth and moon. New York: Springer, 1979.
[54] Anderson D. New Theory of the Earth. Cambridge: Cambridge University Press, USA, 2007.
[55] Hirose K. Reviews of Geophysics, 2006, 44(3): 3001.
[56] Watt J, Davies G, O’Connell R. Reviews of Geophysics, 1976, 14(4): 541.
[57] Dziewonski A, Anderson D. Physics of the Earth and Planetary Interiors, 1981, 25(4): 297.
[58] Murakami M, Ohishi Y, Hirao N,et al. Nature, 2012, 485(7396): 90. |
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