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Recent advances in high-pressure science and technology 被引量:12

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摘要 Recently we are witnessing the boom of high-pressure science and technology from a small niche field to becoming a major dimension in physical sciences.One of the most important technological advances is the integration of synchrotron nanotechnology with the minute samples at ultrahigh pressures.Applications of high pressure have greatly enhanced our understanding of the electronic,phonon,and doping effects on the newly emerged graphene and related 2D layered materials.High pressure has created exotic stoichiometry even in common Group 17,15,and 14 compounds and drastically altered the basic σ and π bonding of organic compounds.Differential pressure measurements enable us to study the rheology and flow of mantle minerals in solid state,thus quantitatively constraining the geodynamics.They also introduce a new approach to understand defect and plastic deformations of nano particles.These examples open new frontiers of high-pressure research.
出处 《Matter and Radiation at Extremes》 SCIE EI CAS 2016年第1期59-75,共17页 极端条件下的物质与辐射(英文)
基金 the support of NSAF Grant No.U1530402.
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  • 1Karato, S. I., Dupas-Bruzek, C., Rubie, D. C., 1998. Plastic Deformation of Silicate Spinel under the Transition Zone Conditions of the Earth's Mantle. Nature, 395(6699): 266-269.
  • 2Kavner, A., Duffy, T. S., 2001. Strength and Elasticity of Ringwoodite at Upper Mantle Pressures. Geophys. Res. Lett., 28(14): 2691-2694.
  • 3Kawazoe, T., Nishiyama, N., Nishihara, N., et al., 2010. Deformation Experiment at P-T Conditions of the Mantle Transition Zone Using D-DIA Apparatus. Phys. Earth Planet. Inter. (in Press).
  • 4Kawazoe, T., Nishiyama, N., Nishihara, Y., et al., 2010. Pressure Generation to 25 GPa Using a Cubic Anvil Apparatus with a Multi-anvil 6-6 Assembly. High Press. Res., 30(1): 167-174.
  • 5Nishiyama, N., Wang, Y. B., Sanehira, T., et al., 2008. Development of the Multi-anvil Assembly 6-6 for DIA and D-DIA Type High-Pressure Apparatuses. High Press. Res., 28(3): 307-314.
  • 6Nishiyama, N., Wang, Y. B., Uchida, T., et al., 2005. Pressure and Strain Dependence of the Strength of Sintered Polycrystalline Mg2SiO4 Ringwoodite. Geophys. Res. Lett., 32(4).
  • 7Peltier, W. R., 1998. Postglacial Variation in the Level of the Sea: Implications for Climate Dynamics and Solid-Earth Geophysics. Rev. Geophys., 36(4): 603-689.
  • 8Torii, Y., Yoshioka, S., 2007. Physical Conditions for Producing Slab Stagnation: Constraints of the Clapeyron Slope, Mantle Viscosity, Trench Retreat, and Dip Angles. Tectonophysics, 445(3-4): 200-209.
  • 9Wang, Y. B., Durham, W. B., Getting, I. C., et al., 2003. The Deformation-DIA: A New Apparatus for High Temperature Triaxial Deformation to Pressures up to 15 GPa. Rev. Sci. Instrum., 74(6): 3002-3011.
  • 10Wenk, H. R., Ischia, G., Nishiyama, N., et al., 2005. Texture Development and Deformation Mechanisms in Ringwoodite. Phys. Earth Planet. Inter., 152(3): 191-199.

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