论文信息 - High‐pressure elastic properties of major materials of Earth's mantle from first principles

High‐pressure elastic properties of major materials of Earth's mantle from first principles

The elasticity of materials is important for our understanding of processes ranging from brittle failure, to flexure, to the propagation of elastic waves. Seismologically revealed structure of the Earth's mantle, including the radial (one‐dimensional) profile, lateral heterogeneity, and anisotropy are determined largely by the elasticity of the materials that make up this region. Despite its importance to geophysics, our knowledge of the elasticity of potentially relevant mineral phases at conditions typical of the Earth's mantle is still limited: Measuring the elastic constants at elevated pressure‐temperature conditions in the laboratory remains a major challenge. Over the past several years, another approach has been developed based on first‐principles quantum mechanical theory. First‐principles calculations provide the ideal complement to the laboratory approach because they require no input from experiment; that is, there are no free parameters in the theory. Such calculations have true predictive power and can supply critical information including that which is difficult to measure experimentally. A review of high‐pressure theoretical studies of major mantle phases shows a wide diversity of elastic behavior among important tetrahedrally and octahedrally coordinated Mg and Ca silicates and Mg, Ca, Al, and Si oxides. This is particularly apparent in the acoustic anisotropy, which is essential for understanding the relationship between seismically observed anisotropy and mantle flow. The acoustic anisotropy of the phases studied varies from zero to more than 50% and is found to depend on pressure strongly, and in some cases nonmonotonically. For example, the anisotropy in MgO decreases with pressure up to 15 GPa before increasing upon further compression, reaching 50% at a pressure of 130 GPa. Compression also has a strong effect on the elasticity through pressure‐induced phase transitions in several systems. For example, the transition from stishovite to CaCl2 structure in silica is accompanied by a discontinuous change in the shear (S) wave velocity that is so large (60%) that it may be observable seismologically. Unifying patterns emerge as well: Eulerian finite strain theory is found to provide a good description of the pressure dependence of the elastic constants for most phases. This is in contrast to an evaluation of Birch’s law, which shows that this systematic accounts only roughly for the effect of pressure, composition, and structure on the longitudinal (P) wave velocity. The growing body of theoretical work now allows a detailed comparison with seismological observations. The athermal elastic wave velocities of most important mantle phases are found to be higher than the seismic wave velocities of the mantle by amounts that are consistent with the anticipated effects of temperature and iron content on the P and S wave velocities of the phases studied. An examination of future directions focuses on strategies for extending first‐principles studies to more challenging but geophysically relevant situations such as solid solutions, high‐temperature conditions, and mineral composites.

[1] P. Shearer. Upper Mantle Seismic Discontinuities , 2013 .

[2] P. M. Shearer,et al. Seismic Models of the Earth , 2013 .

[3] L. Ruff. 33 State of stress within the earth , 2002 .

[4] B. Kiefer,et al. Structure and elasticity of wadsleyite at high pressures , 2001 .

[5] Bijaya B. Karki,et al. Origin of lateral variation of seismic wave velocities and density in the deep mantle , 2001 .

[6] G. D. Price,et al. Ab initio elasticity and thermal equation of state of MgSiO3 perovskite , 2001 .

[7] H. Mao,et al. Elasticity of MgO and a primary pressure scale to 55 GPa. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[8] B. Karki,et al. Ab initio structure of MgSiO3 ilmenite at high pressure , 2000 .

[9] B. Karki,et al. High-pressure elasticity of alumina studied by first principles , 1999 .

[10] Stefano de Gironcoli,et al. First-principles determination of elastic anisotropy and wave velocities of MgO at lower mantle conditions , 1999, Science.

[11] J. Tromp,et al. Normal-mode and free-Air gravity constraints on lateral variations in velocity and density of Earth's mantle , 1999, Science.

[12] L. Stixrude,et al. Seismic velocities of major silicate and oxide phases of the lower mantle , 1999 .

[13] S. Sinogeikin,et al. Single-crystal elasticity of mgo at high pressure , 1999 .

[14] London,et al. Structure and dynamics of liquid iron under Earth’s core conditions , 1999, cond-mat/9905319.

[15] J. Ángyán,et al. Polymorphism in silica studied in the local density and generalized-gradient approximations , 1999 .

[16] R. Cohen,et al. First-principles elastic constants for the hcp transition metals Fe, Co, and Re at high pressure (vol 60, pg 791, 1999) , 1999, cond-mat/9904431.

[17] R. Hilst,et al. Compositional heterogeneity in the bottom 1000 kilometers of Earth's mantle: toward a hybrid convection model , 1999, Science.

[18] S. Karato,et al. High pressure elastic anisotropy of MgSiO3 perovskite and geophysical implications , 1998 .

[19] S. Karato. Some remarks on the origin of seismic anisotropy in the D” layer , 1998 .

[20] M. Hanfland,et al. Pressure-induced landau-type transition in stishovite , 1998, Science.

[21] J. Tromp,et al. Theoretical Global Seismology , 1998 .

[22] Liebermann,et al. Ultrasonic shear wave velocities of MgSiO3 perovskite at 8 GPa and 800 K and lower mantle composition , 1998, Science.

[23] B. Li. Elastic Moduli of Wadsleyite (-Mg2SiO4) to 7Gigapascals and 873Kelvin , 1998 .

[24] J. Crain,et al. First‐principles determination of elastic properties of CaSiO3 perovskite at lower mantle pressures , 1998 .

[25] H. Mao,et al. Brillouin scattering and X-ray diffraction of San Carlos olivine: direct pressure determination to 32 GPa , 1998 .

[26] J. Crain,et al. Structure and elasticity of CaO at high pressure , 1998 .

[27] Stefano de Gironcoli,et al. STRUCTURAL AND ELECTRONIC PROPERTIES OF A WIDE-GAP QUATERNARY SOLID SOLUTION : (ZN, MG) (S, SE) , 1998 .

[28] H. Fujisawa. Elastic wave velocities of forsterite and its β‐spinel form and chemical boundary hypothesis for the 410‐km discontinuity , 1998 .

[29] Thorne Lay,et al. The core–mantle boundary layer and deep Earth dynamics , 1998, Nature.

[30] S. Karato. Seismic Anisotropy in the Deep Mantle, Boundary Layers and the Geometry of Mantle Convection , 1998 .

[31] J. Montagner. Where Can Seismic Anisotropy Be Detected in the Earth’s Mantle? In Boundary Layers... , 1998 .

[32] J. Crain,et al. Ab initio elasticity of three high‐pressure polymorphs of silica , 1997 .

[33] L. Stixrude,et al. Calculated elastic constants and anisotropy of Mg2SiO4 spinel at high pressure , 1997 .

[34] J. Crain,et al. Elastic instabilities in crystals from ab initio stress - strain relations , 1997 .

[35] L. Stixrude,et al. Elastic constants and anisotropy of forsterite at high pressure , 1997 .

[36] L. Stixrude. Structure and sharpness of phase transitions and mantle discontinuities , 1997 .

[37] R. Cohen,et al. Effects of Pressure on Diffusion and Vacancy Formation in MgO from Nonempirical Free-Energy Integrations , 1997, cond-mat/9706130.

[38] J. Crain,et al. Elastic properties of orthorhombic MgSiO3 perovskite at lower mantle pressures , 1997 .

[39] T. Lay,et al. Lateral variations in lowermost mantle shear wave anisotropy beneath the north Pacific and Alaska , 1997 .

[40] E. R. Engdahl,et al. Evidence for deep mantle circulation from global tomography , 1997, Nature.

[41] L. Slutsky,et al. The elastic constants of a pyrope‐grossular‐almandine garnet to 20 Gpa , 1997 .

[42] H. Mao,et al. Single-crystal elasticity of β-Mg2SiO4 to the pressure of the 410 km seismic discontinuity in the Earth's mantle , 1997 .

[43] J. Chelikowsky,et al. Phase transitions in quartz near the amorphization transformation. , 1997 .

[44] J. Crain,et al. Ab initio studies of high-pressure structural transformations in silica , 1997 .

[45] Burke,et al. Generalized Gradient Approximation Made Simple. , 1996, Physical review letters.

[46] T. Jordan,et al. Seismic structure of the upper mantle in a central Pacific corridor , 1996 .

[47] J. Woodhouse,et al. Ratio of relative S to P velocity heterogeneity in the lower mantle , 1996 .

[48] H. Mao,et al. Sound velocity and elasticity of single‐crystal forsterite to 16 GPa , 1996 .

[49] G. Laske,et al. A shear - velocity model of the mantle , 1996, Philosophical Transactions of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences.

[50] Wills,et al. First-principles theory of iron up to earth-core pressures: Structural, vibrational, and elastic properties. , 1996, Physical review. B, Condensed matter.

[51] P. Silver,et al. Constraints from seismic anisotropy on the nature of the lowermost mantle , 1996, Nature.

[52] D. Helmberger,et al. Seismic detection of a thin laterally varying boundary layer at the base of the mantle beneath the central‐Pacific , 1996 .

[53] B. Kennett,et al. How to reconcile body-wave and normal-mode reference earth models , 1996 .

[54] G. D. Price,et al. High pressure studies of Mantle minerals by ab initio variable cell shape molecular dynamics , 1996 .

[55] Hamann. Generalized gradient theory for silica phase transitions. , 1996, Physical review letters.

[56] W. Liu,et al. Thermal equation of state of CaGeO3 perovskite , 1996 .

[57] Li,et al. Mechanical instabilities of homogeneous crystals. , 1995, Physical review. B, Condensed matter.

[58] Wolverton,et al. Ising-like description of structurally relaxed ordered and disordered alloys. , 1995, Physical review letters.

[59] Tang,et al. Atomic size effects in pressure-induced amorphization of a binary covalent lattice. , 1995, Physical review letters.

[60] G. D. Price,et al. Ab initio study of MgSiO3 C2/c enstatite , 1995 .

[61] Geoffrey D. Price,et al. Ab initio study of MgSiO3 and CaSiO3 perovskites at lower-mantle pressures , 1995 .

[62] P. Silver,et al. Laboratory and seismological observations of lower mantle isotropy , 1995 .

[63] P. Silver,et al. Anisotropic loci in the mantle beneath central Peru , 1995 .

[64] Nastar,et al. Tight-binding calculation of the elastic constants of fcc and hcp transition metals. , 1995, Physical review. B, Condensed matter.

[65] Duffy,et al. Equation of state and shear strength at multimegabar pressures: Magnesium oxide to 227 GPa. , 1995, Physical review letters.

[66] C. Bina,et al. Frequency dependence of the visibility and depths of mantle seismic discontinuities , 1994 .

[67] A. Yeganeh-Haeri. Synthesis and re-investigation of the elastic properties of single-crystal magnesium silicate perovskite , 1994 .

[68] Mizushima,et al. Ideal crystal stability and pressure-induced phase transition in silicon. , 1994, Physical review. B, Condensed matter.

[69] Cohen,et al. Iron at high pressure: Linearized-augmented-plane-wave computations in the generalized-gradient approximation. , 1994, Physical review. B, Condensed matter.

[70] D. L. Anderson,et al. Mineral physics constraints on the chemical composition of the Earth's lower mantle , 1994 .

[71] David J. Singh. Planewaves, Pseudopotentials, and the LAPW Method , 1993 .

[72] Anil K. Jain,et al. Texture Analysis , 2018, Handbook of Image Processing and Computer Vision.

[73] D. Sherman. Equation of state, elastic properties, and stability of CaSiO3 perovskite: First principles (periodic Hartree‐Fock) results , 1993 .

[74] R. Cohen,et al. Stability of orthorhombic MgSiO3 perovskite in the Earth's lower mantle , 1993, Nature.

[75] S. Karato,et al. Importance of anelasticity in the interpretation of seismic tomography , 1993 .

[76] Price,et al. Ab initio molecular dynamics with variable cell shape: Application to MgSiO3. , 1993, Physical review letters.

[77] E. Salje,et al. Phase transitions in ferroelastic and co-elastic crystals , 1993 .

[78] T. Arias,et al. Iterative minimization techniques for ab initio total energy calculations: molecular dynamics and co , 1992 .

[79] H. Mao,et al. Thermoelasticity of Silicate Perovskite and Magnesiow�stite and Stratification of the Earth's Mantle , 1992, Science.

[80] A. Campbell,et al. A High-Pressure Test of Birch's Law , 1992, Science.

[81] O. Anderson,et al. The relationship between shear and compressional velocities at high pressures: Reconciliation of seismic tomography and mineral physics , 1992 .

[82] O. Anderson,et al. High‐temperature elastic constant data on minerals relevant to geophysics , 1992 .

[83] Guust Nolet,et al. Tomographic imaging of subducted lithosphere below northwest Pacific island arcs , 1991, Nature.

[84] R. Wentzcovitch,et al. Invariant molecular-dynamics approach to structural phase transitions. , 1991, Physical review. B, Condensed matter.

[85] R. Cohen. Bonding and elasticity of stishovite SiO2 at high pressure: Linearized augmented plane wave calculations , 1991 .

[86] Renata M. Wentzcovitch,et al. First principles molecular dynamics of Li: Test of a new algorithm , 1991 .

[87] Stefano de Gironcoli,et al. Structure and thermodynamics of SixGe1-x alloys from ab initio Monte Carlo simulations. , 1991, Physical review letters.

[88] Martins,et al. Efficient pseudopotentials for plane-wave calculations. , 1991, Physical review. B, Condensed matter.

[89] S. Karato,et al. Defect microdynamics in minerals and solid state mechanisms of seismic wave attenuation and velocity dispersion in the mantle , 1990 .

[90] M. Mehl,et al. Calculated elastic and thermal properties of MGO at high pressures and temperatures , 1990 .

[91] D. Vanderbilt,et al. Soft self-consistent pseudopotentials in a generalized eigenvalue formalism. , 1990, Physical review. B, Condensed matter.

[92] H. Mao,et al. Stability and equation of state of CaSiO3‐Perovskite to 134 GPa , 1989 .

[93] Jepsen,et al. Ground-state properties of third-row elements with nonlocal density functionals. , 1989, Physical review. B, Condensed matter.

[94] R. Jeanloz,et al. Density and composition of the lower mantle , 1989, Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences.

[95] R. O. Jones,et al. The density functional formalism, its applications and prospects , 1989 .

[96] N. Ribe. Seismic anisotropy and mantle flow , 1989 .

[97] Warren E. Pickett,et al. Pseudopotential methods in condensed matter applications , 1989 .

[98] M. Mehl,et al. Linearized augmented plane wave electronic structure calculations for MgO and CaO , 1988 .

[99] R. Jeanloz,et al. Universal equation of state. , 1988, Physical review. B, Condensed matter.

[100] Don L. Anderson,et al. Thermally Induced Phase Changes, Lateral Heterogeneity of the Mantle, Continental Roots, and Deep Slab Anomalies , 1987 .

[101] J. Watt. POLYXSTAL: A FORTRAN program to calculate average elastic properties of minerals from single-crystal elasticity data , 1987 .

[102] Ronald E. Cohen,et al. Elasticity and equation of state of MgSiO3 perovskite , 1987 .

[103] M. Rivers,et al. Ultrasonic studies of silicate melts , 1987 .

[104] Testa,et al. Green's-function approach to linear response in solids. , 1987, Physical review letters.

[105] Takeo Matsumoto,et al. Computational model of the structural and elastic properties of the ilmenite and perovskite phases of MgSiO3 , 1987 .

[106] Boyer,et al. Potential-induced breathing model for the elastic moduli and high-pressure behavior of the cubic alkaline-earth oxides. , 1986, Physical review. B, Condensed matter.