Plamy gorąca i pióropusze płaszcza : obecny stan koncepcji

• Autorzy: Malinowski M.

Warianty tytułu

EN

The state of the art of the hotspot and mantle plume theory

• Języki publikacji: PL

Abstrakty

EN

In this paper, the historical background for the theory explaining the mid-plate volcanism by introducing hotspot and mantle plume has been given. Subsequently, as supported by geological observations, geochemical data, results of the statistical analysis of the global hotspot distribution and recent seismological surveys, current views on the origin of such phenomenon has been presented.

Słowa kluczowe

PL

teoria plam; źródła plam gorąca; model geochemiczny płaszcza; pióropusz płaszcza; analiza statystyczna

EN

hotspots; mantle plume; statistical analysis

• Wydawca: Polskie Towarzystwa Geofizyczne ; Komitet Geofizyki PAN
• Czasopismo: Przegląd Geofizyczny
• Rocznik: 2002
• Tom: Z. 1-2
• Strony: 61--79
• Opis fizyczny: Bibliogr. 76 poz., rys., wykr.

Twórcy

autor

Malinowski M.

• Instytut Geofizyki PAN, Warszawa, Polska

Bibliografia

• [1] Akaogi M., Ito E., 1999, Calorimetric study on majorite-perovskite transition in the system Mg4Si4O12-Mg3Al2Si3O12: transition boundaries with positive pressure-temperature slopes. Phys. Earh. Planet. Int., 114, 129-140.
• [2] Anderson D. L., 1995, Lithosphere. Asthenosphere, and Perisphere. Rev. Geophys, 33, 125-149.
• [3] Anderson D. L., 1998a, The EDGES of the Mantle [W:] The Core — Mantle Boundary Region, red. M. Gurnis, M. Wysession, E. Knittle, B. Buffet. AGU Geodynamics Series, t. 28, 255-271. AGU, Washington, DC.
• [4] Anderson D. L., 1998b, The Helium Paradoxes. Proc. Natl. Acad. Sci. USA, 95, 4822-4827.
• [5] Anderson D. L., 1998c, The Scales o f Mantle Convection. Tectonophys., 284, 1-17.
• [6] Anderson D. L., 1999, A Theory of the Earth: Hutton and Humpty Dumpty and Holmes. [W:] James Hutton — Present and Future, red. G. Craig, J. Hull. Special Publications, t. 150, 13-35. Geol. Soc. of London.
• [7] Anderson D. L., 2000, The Thermal State of the Upper Mantle: No Role for Mantle Plumes. Geophys. Res. Lett., 27, 3623-3626.
• [8] Anderson D. L., Tanimoto T., Zhang Y.-S., 1992, Plate Tectonics and Hotspots: The Third Dimension. Science, 256, 1645-1651.
• [9] Bailey D. K., 1983, The chemical and thermal evolution of rifts. Tectonophys., 94, 585-597.
• [10] Becker T. W., Boschi L., 2001, A comparison of tomographic and geodynamic mantle models. Geochem. Geophys. Geosyst., 2001GC000168.
• [11] Bijwaard H., Spakman W., 1999, Tomographic Evidence for a Narrow Whole Mantle Plume Below Iceland. Earth Planet. Sci. Lett., 166, 121-126.
• [12] Boschi L., Dziewoński A. M., 1999, High- and Low-resolution Images of the Earth's Mantle: Implications of Different Approaches to Tomographic Modeling. J. Geophys. Res., 104, 25567-25594.
• [13] Burke K., Wilson J. T., 1976, Hotspots on the Earth's Surface. Sci. Amer., 235, 46-57.
• [14] Čadek O., Kývalová H., Yuen D. A., 1995, Geodynamical implications from the correlation of surface geology and seismic tomographic structure. Earth Planet. Sci. Lett., 136, 615-627.
• [15] Coffin M., Eldholm O., 1994, Large igneous provinces: crustal structure, dimensions, and external consequences. Rev. Geophys., 16, 1-36.
• [16] Crough T. S., 1983, Hotspot Swells. Annu. Rev. Earth Planet. Sci., 11, 163-193.
• [17] Crough T. S., Jurdy D. M., 1980. Subducted Lithosphere, Hotspots and the Geoid. Earth Planet. Sci. Lett., 48, 15-22.
• [18] Davaille A., 1999, Simultaneous Generation of Hotspots and Superswells by Convection in a Heterogeneous Planetary Mantle. Nature, 402, 756-760.
• [19] Davies G. F. 1988, Ocean Bathymetry and Mantle Convection, J. Large-scale flow and hotspots. J. Geophys. Res., 93, 10467-10480.
• [20] Dewey J. F., Burke K., 1974, Hotspots and Continental Break-up: Implications for Colisional Orogeny. Geology, 2, 57-60.
• [21] Dziewonski A. M., Anderson D. L., 1981, Preliminary Reference Earth Model. Phys. Earh. Planet. Int., 25, 297-356.
• [22] Foulger G. R., Pritchard M. J., Julian B. R., Evans J. R., Allen R. M., Nolet G., Morgan W. J., Bergsson B. H., Erlendsson P., Jakobsdottir S., Ragnarsson S., Stefansson R., Vogfjörd K., 2001, Seismic tomography shows that upwelling beneath Iceland is confined to the upper mantle. Geophys. J. Int.. 146, 504-530.
• [23] Griffiths R. W., Campbell I. H., 1990, Stirring and Structure in Mantle Plumes. Earth Planet. Sci. Lett., 99. 66-78.
• [24] Haddon R. A. W., Cleary J. R., 1974, Evidence for Scattering of Seismic PKP Waves Near the Mantle-Core Boundary. Phys. Earh. Planet. Int., 8, 211-234.
• [25] Helmberger D. V., Wen L., Ding X., 1998, Seismic Evidence That the Source of the Iceland Hotspot Lies At the Core-mantle Boundary. Nature, 396, 251-255.
• [26] Hofmann A. W., 1997, Mantle Geochemistry: The Message from Oceanic Volcanism. Nature, 385, 219-229.
• [27] Kaban M. K., Schwintzer P., Tikhotsky A., 1999, A Global Isostatic Model of the Earth. Geophys. J. Int., 136, 519-536.
• [28] Kanasewich E. R., Ellis R. M., Chapman C. M., Gutowski P. R., 1972, Teleseismic Array Evidence for Inhomogeneities in the Lower Mantle and the Origin of the Hawaiian Islands. Nature, 239, 99-100.
• [29] Karato S., Jung H., 1998, Water, Partial Melting and the Origin of the Seismic Low Velocity and High Attenuation Zone in the Upper Mantle. Earth Planet. Sci. Lett., 157, 193-207.
• [30] Kaula W. M., 1967, Theory of Statistical Analysis of Data Distributed Over a Sphere. Rev. Geophys., 5, 83-107.
• [31] Kedar S., Anderson D. L., Stevenson D. J., 1993, Relationship Between Hotspots and Mantle Structure: Correlation with Whole Mantle Seismic Tomography. [W:] Flow and Creep in the Solar System: Observations, Modeling and Theory, red. D. Stone, K. Runcorn, 249-259. Kluwer Academic Publ.
• [32] Kellog L. H., Hager B. H., van der Hilst R. D., 1999, Compositional stratification in the deep mantle. Science, 283, 1881-1884.
• [33] King S. D., Anderson D. L., 1995, An alternative mechanism of flood basalt formation. Earth Planet. Sci. Lett., 136, 269-279.
• [34] King S. D., Ritsema J., 2000, African Hot Spot Volcanism: Small-Scale Convection in the Upper Mantle Beneath Cratons. Science, 290, 1137-1140.
• [35] Loper D. E., 1991, Mantle Plumes. Tectonophys., 187, 373-384.
• [36] Loper D. E., Stacey F. D., 1983, The Dynamical and Thermal Structure of Deep Mantle Plumes. Phys. Earh. Planet. Int., 33, 304-317.
• [37] Malinowski M., 2000a, Analiza fraktalna — nowe podejście do wulkanizmu śródoceanicznego. [W:] Referaty laureatów studenckich sesji naukowych górników, red. B. Jabłońska-Firek, 55-62. Uczelniane Wydawnictwa Naukowo-Dydaktyczne AGH w Krakowie.
• [38] Malinowski M., 2000b, The Fractal Analysis of the Global Hotspot Distribution. Geophys. Res. Abstracts, 2, 148.
• [39] Malinowski M., 2001, Hotspots and Mantle Plumes: Constraints From Statistical Analysis. Acta Geophys. Polon. (w druku).
• [40] Megnin C., Romanowicz B., 2000, The 3D Shear Velocity Structure of the Mantle from the Inversion of Body, Surface, and Higher Mode Waveforms. Geophys. J. Int., 143, 709-728.
• [41] Minster J. B., Jordan T. H., 1978, Present — day plate motions. J. Geophys. Res., 83, 5331-5354.
• [42] Molnar P., Atwater T., 1973, Relative Motion of Hot Spots in the Mantle. Nature, 246, 288-291.
• [43] Molnar P., Stock J., 1987, Relative motions o f hotspots in the Pacific, Atlantic, and Indian oceans since Late Cretaceous time. Nature, 327, 587-591.
• [44] Morgan W. J., 1971, Convection Plumes in the Lower Mantle. Nature. 230, 42-43.
• [45] Morgan W. J., 1972, Deep Mantle Convection Plumes and Plate Motions. AAPG Bulletin, 56, 203-213.
• [46] Mueller B., Reinecker J., Fuchs K., 2000, The 2000 Release of the World Stress Map. Available Online At: www.wsm.physik.uni-karlsruhe.de/pub.
• [47] Ray T. W., Anderson D. L., 1994, Spherical Disharmonies in the Earth Sciences and the Spatial Solution: Ridges, Hotspots, Slabs, Geochemistry and Tomography Correlation. J. Geophys. Res., 99, 9605-9614.
• [48] Rhodes M., Davies J. H., 2001, Tomographic imaging of multiple mantle plumes in the uppermost lower mantle. Geophys. J. Int., 147, 88-92.
• [49] Richards M. A., Duncan R. A., Courtillot V. E., 1989, Flood Basalts and Hotspots Tracks: Plume Heads and Tails. Science, 246, 103-107.
• [50] Richards M. A., Griffiths R. W., 1988, Deflection of plumes by mantle shear flow: experimental results and a simple theory. Geophys. J., 94, 367-376.
• [51] Richards M. A., Hager B. H., Sleep N. H., 1988, Dynamically Suported Geoid Highs Over Hotspots: Observation and Theory. J. Geophys. Res., 93, 7690-7708.
• [52] Ritsema J., van Heijst H. J., Woodhause J. H., 1999, Complex Shear Wave Velocity Structure Imaged Beneath Africa and Iceland. Science, 286, 1925-1928.
• [53] Russell S. A., Lay T., Garnero E. J., 1998, Seismic Evidence for Small-scale Dynamics in the Lowermost Mantle At the Root of the Hawaiian Hotspot. Nature, 396, 255-258.
• [54] Shen Y., Solomon S. C., Bjarnason I., Wolfe C. J., 1998, Seismic Evidence for a Lower Mantle Origin of the Iceland Plume. Nature, 395, 62-65.
• [55] Sheth H. C., 1999, Flood Basalts and Large Igneous Provinces from Deep Mantle Plumes: Fact, Fiction and Fallacy. Tectonophys., 311, 1-29.
• [56] Sleep N. H., 1992, Hotspot Volcanism and Mantle Plumes. Annu. Rev. Earth Planet. Sci., 20, 19-43.
• [57] Smithsonian, 1995, Global Volcanism Program. Washington DC. Online at: www.nmnh.si.edu/gvp.
• [58] Stacey F. D., 1992, Physics of the Earth. Brisbane, Brookfield Press.
• [59] Stacey F. D., Loper D. E., 1983, The Thermal Boundary Layer Interpretation of D" and its Role as a Plume Source. Phys. Earh. Planet. Int., 33, 45-55.
• [60] Steinberger B., 2000a, Plumes in a Converting Mantle: Models And Observation for Individual Hotspots. J. Geophys. Res., 105, 11127-11152.
• [61] Steinberger B., 2000b, Slabs in the Lower Mantle — Results of Dynamic Modelling Compared with Tomographic Images and the Geoid. Phys. Earh. Planet. Int., 118, 241-257.
• [62] Steinberger B., O'Connell R. J., 1998, Advection of Plumes in Mantle Flow: Implications for Hotspot Motion, Mantle Viscosity and Plume Distribution. Geophys. J. Int., 132, 412-434.
• [63] Steinberger B., Schmelling H., Marquart G., 2001, Large-scale lithospheric stress field and topography induced by global mantle circulation. Earth Planet. Sci. Lett., 186, 75-91.
• [64] Tackley P. J., 2000, Mantle Convection and Plate Tectonics: Toward an Integrated Physical and Chemical Theory. Science, 288, 2002-2007.
• [65] Tanimoto T., 1990, Long Wavelength S-wave Velocity Structure Throughout the Mantle. Geophys. J. Int., 100, 327-336.
• [66] Van Keken P., 1997, Evolution of Starting Mantle Plumes: A Comparison Between Numerical and Laboratory Models. Earth Planet. Sci. Lett., 148, 1-11.
• [67] Vogt P. R., 1974, Volcano Spacing. Fractures, and Thickness of the Lithosphere. Earth Planet. Sci. Lett., 21, 235-252.
• [68] Vogt P. R. 1981, On the Applicability of Thermal Conduction Models to Mid-plate Volcanism: Comments on a Paper by Gass et al. J. Geophys. Res., 86, 950-960.
• [69] Wen L., Anderson D. L., 1997. Slabs. Hotspots, Cratons and Mantle Convection Revealed from Residual Seismic Tomography in the Upper Mantle. Phys. Earh. Planet. Int., 99, 131-143.
• [70] Whitehead J. A., Luther D., 1975, Dynamics of Laboratory Diapir and Plume Models. J. Geophys. Res., 80, 705-717.
• [71] Wilson J. T., 1963, A Possible Origin of the Hawaiian Islands. Can. J. Phys., 41, 863-870.
• [72] Wilson J. T., 1973, Mantle Plumes and Plate Motions. Tectonophys., 19, 149-164.
• [73] Wolfe C. J., Bjarnason I., van Decar J. C., Solomon S. C., 1997, Seismic Structure of the Iceland Mantle Plume. Nature, 385, 245-247.
• [74] Yamaji A., 1992, Periodic Hotspot Distribution and Small Scale Convection in the Upper Mantle. Earth Planet. Sci. Lett., 109, 107-116.
• [75] Zindler A., Hart S., 1986, Chemical geodynamics. Annu. Rev. Earth Planet. Sci., 14, 493-570.
• [76] Zonenshein L. P., Kuzmin M. I., Natapov L. M., 1990, Geology of the USSR: A Plate-Tectonics Synthesis. Geodyn. Ser. t. 21, AGU, Washington DC.