On the magnetic field of the oceans

Vadim Gordienko

doi:10.24028/gj.v46i5.300743

Authors

Vadim Gordienko Subbotin Institute of Geophysics,National Academy of Sciences of Ukraine, Ukraine http://orcid.org/0000-0001-9430-7801

DOI:

https://doi.org/10.24028/gj.v46i5.300743

Keywords:

magnetic field of the oceans; band anomalies; anomaly source models.

Abstract

The authors of the idea of linking strip magnetic anomalies with the formation of their sources under the influence of the Earth’s alternating magnetic field thought it possible to study the movement of lithospheric plates with their help. Most of them quickly abandoned such intentions. Nevertheless, most geophysicists in the world believe this is possible. The material accumulated over the 60 years of the idea’s existence contradicts it. The article reviews the currently known facts from the standpoint of plate tectonics and from the point of view of alternative ideas about the formation of the oceans and their crust. The discussion focuses on the spatial distribution and intensity of band anomalies of the oceans’ magnetic field and on their sources being restricted to certain types of rocks and layers of sections of the Earth’s crust and upper mantle. According to the author, they cannot be explained in any way by the plate tectonics concept. This conclusion is consistent with the long-standing results of many geophysicists. Recognition of this fact is restrained only by the unwillingness to abandon ingrained stereotypes. A variant of the process of oceanization of the continental crust proposed by the author, most of all reminiscent of continental endogenous regimes, reminiscent of rifting, accommodates models for the formation of band anomalies without involving sources with reverse magnetization. In oceanic basins, such sources have not been found at all. They occur in limited areas, but their experimentally determined parameters do not allow for an explanation of the observed magnetic field.

References

Absalyamov, S.S. (2004). Influence of destruction of rocks at elevated pressure on their magnetic properties. Doctor’s thesis. Ufa, 36 p. (in Russian).

Belousov, V.V. (1982). Transitional zones between continents and oceans. Moscow: Nedra, 152 p. (in Russian).

Blakely, R. (1976). An age-dependent two-layer model of marine magnetic anomalies. The Geophysics of the Pacific Ocean basin and its margin, 19, 227―234. https://doi.org/10.1029/GM019p0227.

Buallo, G. (1985). Geology of the margins of the continents. Moscow: Mir, 155 p. (in Russian).

Cox, A., Blakely, R., & Phillips, J. (1972). A two layer model for marine magnetic anomalies. EOS. Trans. AGU, 53, 94.

Cox, A., & Hart, D. (1989). Plate tectonics. Moscow: Mir, 427 p. (in Russian).

Dunlop, D., & Prévot, M. (1982). Magnetic properties and opaque mineralogy of drilled submarine intrusive rocks. Geophysical Journal International, 69(3), 763―802. https://doi.org/ 10.1111/j.1365-246X.1982.tb02774.x.

Gordin, V.M. (2007). Selected works and memories. Moscow: IPE RAS, 138 p. (in Russian).

Gordin, V.M., & Zolotov, I.G. (1989). Modeling of the magnetoactive layer of the oceanic lithosphere (Theoretical and methodological aspects). Moscow: IPE AN USSR, 181 p. (in Russian).

Gordienko, V.V. (2018). On the motion of lithospheric plates in the oceans and transition zones. Geofizicheskiy Zhurnal, 40(3), 129―144. https://doi.org/10.24028/gzh.0203-3100.v40i3.2018.137181 (in Russian).

Gordienko, V.V. (2017).Thermal processes, geodynamics. Deposits, 284 p. Retrieved from https://d4d10b6a-c83d-45d7-b6dcb2c3ccafe1ce.filesusr.com/ugd/6d9890_c2445800a51b49adb03b8f949f3d6abb.pdf.

Gordienko, V.V., & Gordienko, L.Ya. (2018). Plate movements and earthquakes. Geologiya i korysnі kopalyny svіtovogo oceanu, (4), 5―19 (in Russian).

Goryainov, I.N., & Smekalov, A.S. (1991). On the nature of strip magnetic anomalies in the World Ocean (interference-tectonomagnetic model). Doklady Academii Nauk SSSR, 321(3), 563―568 (in Russian).

Gubbins, D., & Herrero-Bervera, E. (Eds.). (2007). Encyclopedia of Geomagnetism and Paleomagnetism. Springer, 1054 p. https://doi.org/10. 1007/978-1-4020-4423-6.

Frolov, V.T., & Frolova, T.I. (2011). Origin of the Pacific: 2nd ed. Moscow: MAKS Press, 52 p. (in Russian).

Johnson, H. (1979). Paleomagnetism of igneous rock samples. Retrieved from http://deepseadrilling.org/45/volume/dsdp45_15.pdf.

Kent, D., Honners, B., Opdyke, N., & Fox, P. (1978). Magnetic properties of dredged oceanic gabbros and the source of marine magnetic anomalies. Geophysical Journal International, 55(3), 513―537. https://doi.org/10.1111/j.1365-246X.1978.tb05925.x.

Krasnyy, M.L., Neverov, Yu.P., & Kornev, O.S. (1981). On the material composition of the rocks of the marginal oceanic bar of Hokkaido. New. Aleksandrovsk: IMGG, 21 p. (in Russian).

Kukal, Z.(1987). Speed of geological processes. Moscow: Mir, 246 p. (in Russian).

Leybov, M.B., & Mirlin, E.G. (1978). Modeling the formation of a magnetically active layer at the base of mid-ocean ridges. Fizika Zemli, (7), 54―62 (in Russian).

Lomtev, V.L. (2008). New data on tectonics and magmatism of the NW Pacific. Geologiya i korysnі kopalyny svіtovogo oceanu, (4), 93―105 (in Russian).

Lomtev, V.L. (2011). To the structure and history of the Kuril-Kamchatka deep-sea trench (NW Pacific). Geologiya i korysnі kopalyny svіtovogo oceanu, (3), 36―48 (in Russian).

Lowrie, W. (1977). Intensity and direction of magnetization in oceanic basalts. Journal of the Geological Society, 133, 61―82. https://doi.org/10.1144/gsjgs.133.1.0061.

MacDonald, K., & Fox, P. (1983). Overlapping spreading centres: new accretion geometry on the East Pacific rise. Nature, 301, 55―63. https://doi.org/10.1038/302055a0.

Makarenko, G.F. (1997). Periodicity of basalts, biocrisis, structural symmetry of the Earth. Moscow: Geoinformmark, 98 p. (in Russian).

Matthews, D., & Bath, J. (1967). Formation of magnetic anomaly pattern of Mid-Atlantic ridge. Geophysical Journal International, 13(1-3), 349―357. https://doi.org/10.1111/j.1365-246X. 1967.tb02165.х.

Meyerhoff, A., & Meyerhoff, G. (1974). New global tectonics ― major controversies. In New global tectonics (pp. 377―445). Moscow: Mir (in Russian).

Morley, L. & Larochelle, A. (1964). Palaeomagnetism as a means of dating geological events. In F. Osborne (Ed.), Geochronology in Canada (pp. 39―51). Toronto: University of Toronto Press. https://doi.org/10.3138/9781487586041-007.

Müller, R.D., Sdrolias, M., Gaina, C., & Roest, W.R. (2004). Age spreading rates and spreading asymmetry of the world’s ocean crust. Geochemistry, Geophysics, Geosystems, 9(4).https:// doi.org/10.1029/2007GC001743.

Olsen, K. (Ed.). (1995). Continental Rifts: Evolution, Structure and Tectonics. Amsterdam: Elsevier, 492 p.

Pariso, J., & Johnson, Y. (1993). Do lower crustal rocks record reversals of the Earth’s magnetic field? Magnetic petrology of oceanic gabbros from Ocean Drilling Program Hole 735B. Journal of Geophysical Research, 98(89), 16013―16032. https://doi.org/10.1029/93JB00933.

Pecherskiy, D.M., Tikhonov, L.V., & Zolotarev, B.P. (1979). Magnetism of Atlantic basalts. Izv. Akad. Nauk., Ser. Phizika Zemli, (12), 25―33 (in Russian).

Permanent geomagnetic field. Magnetism of rocks and paleomagnetism: Abstracts of the reports of the II All-Union Congress on Geomagnetism.(1981). Tbilisi: Tbilisi University Publ. House, 200 p. (in Russian).

Peslier, A., Schonbacher, M., Busenmann, H., & Karato, S. (2017). Water in the Earth’s interior: distribution and origin. Space Science Reviews, 212(1-2), 743―810. https://doi.org/10.1007/s11214-017-0387-z.

Popov, K.V., & Shcherbakov, V.P (1994). Magnetic properties of serpentinites raised from the ocean floor. Petromagnetic model of the lithosphere (pp. 19―24). Kiev: Naukova Dumka (in Russian).

Raykevich, M.I. (1990). The nature of the magnetization of igneous rocks of some morphostructures of the western part of the Pacific Ocean. Abstract of dis. Leningrad, 20 p. (in Russian).

Silantiev, S.A., Levskiy, L.K., Arakeliants, M.M., Lebedev, V.A., Bougault, H., & Cannat, M. (2000). Age of igneous and metamorphic events in the MAR: interpretation of K-Ar isotopic dating data. Russian Journal of Earth Sciences, 2(3).

Storetvedt, K., & Longhinos, B. (2011). Evolution of the North Atlantic: Paradigm shifting the offing. NCGT Journal, 59, 8―51.

Udintsev, G.B. (Ed.). (2003). International Geological and Geophysical Atlas of the Pacific Ocean. Moscow-Saint Petersburg: IOC (UNESCO), RAS, FSUE PKO «Cartography», GUNiO, 192 p. (in Russian).

Vasiliev, B.I. (Ed.). (2005). Geological structure and origin of the Pacific Ocean. Vladivostok: Dalnauka, 167 p. (Russian).

Vine, F., & Matthews, D. (1963). Magnetic anomalies over ocean ridges. Nature,199, 947―949.

Vine, F., & Wilson, T. (1965). Magnetic anomalies over a young oceanic ridge off Vancouver Islands. Science, 150, 485―489. https://doi.org/ 10.1126/science.150.3695.485.

On the magnetic field of the oceans

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