Abstract
Deep seismic images around isochron M16 (142 Ma) are presented from three different sites on both flanks of the North Atlantic ocean. The similarity of the acquisition parameters and of the reflective patterns, allows us to perform an identical post-stack processing sequence in order to interpret jointly the three data-sets. Despite the scattered energy produced at the contact between the sedimentary cover and the top of the igneous basement, a reasonable generalised velocity-depth function has been obtained with which to perform seismic migration. The final results provide clearer images of structures in the igneous crust than previously obtained.
The migrated sections show in general rather similar images on the two plates (North America and West Africa), some distinctions can also be deduced from the Individual profiles. A common feature on the three profiles is the blocky character of the top of the igneous basement, which is cut by a series of offsets ranging from 200 to 600 ms. Most of them can be extended down to the base of the upper crust as dipping reflections, and can be interpreted as normal faults. On the American profile, two steeply dipping events show continuity down to the lower crust, dying out as low-angle normal faults (detachment). On the American plate profile, the geometry of the faults suggests a domino-style faulting with most of the steeply dipping events striking ridgewards. On the African plate profiles, the majority of the dipping events also show a ridgeward dip. The upper crust is made up of short and gently dipping events mostly located beneath the basement ridges. An interesting feature is seen on the American profile, where a pair of almost parallel reflections located beneath a basement ridge show an intermittent continuity with a lateral extension of about 5 km. This event could be interpreted as magmatic in origin possibly produced during a high melt production period. The lower crust shows scarce reflectivity on the African profiles, whereas on the American ones it shows a great variety of events. In general the reflectivity is higher on the older side of the lines. From the available data-set it seems that the deep seismic images obtained on both sides of the Atlantic are fairly symmetrical. Some exceptions could he ascribed to small differential changes, between ridge segments, in the spreading rate
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References
Alexander, R.J., Harper, G.D. and Bowman, J.R., Oceanic faulting and fault-controlled subseafloor hydrothermal alteration in the sheeted dicke complex of Josephine ophiolite, J. Geophys. Res., 98, 9731ā9759, 1993.
Banda, E., Ranero, C.R., Danobeitia, J.J., and Rivero, A., Seismic boundaries of the estern Central Atlantic Mesozoic crust from multichannel seismic data, Geol. Soc. Am. Bull., 104, 1340ā1349, 1992.
Claerbout, J.F., Imaging the Earthās Interior, Blackwell Scientific Publications, 1985.
Grindlay, N.R., Fox, P.J., and Vogt, P.R., Morphology and tectonics of the Mid-Atlantic ridge (25Ā°-27Ā°30āS) from seabeam and magnetic data, 97, 6983ā7010, 1992.
Hayes, D.E., Pimm, A.C., Beckmann, J.P., Benson, W.E., Berger, W.H., Roth, P.H., Supko, P.R. and von Rad, U., Initial Reports of Deep Sea Drilling Project, vol XIV, Washington (U.S. Government Printing Office), pp. 157ā215, 1972.
Hayes, D.E., and Rabinowitz, P.D., Mesozoic magnetic lineations and the magnetic quiet zone off northwest Africa, Earth Planet. Sci. Lett., 28, 105ā115, 1975.
Henstock, T.J., Woods, A.W., and White, R.S., The accreation of oceanic crust by episodic sill intrusion, J. Geophys. Res., 98, 4143ā4161, 1993.
Hobbs, R., and Snyder, D., Marine seismic sources used for deep seismic reflection profiling, First Break, 10,417ā426,1992.
Klitgord, K.D., and Schouten, H., Plate kinematics of the Central Atlantic, in Vogt, P.R., and Tucholke, B.E., eds., The geology of North America, the western North Atlantic region, Volume M: Boulder, Colorado, Geophysical Society of America, pp 351ā377, 1986.
McBride, J.H., Henstock, T.J., White, R.S., and Hobbs, R.W., Seismic reflection profiling in deepwater: avoiding spurious reflectivity at lower-crustal and upper-mantle traveltimes, Tectonophysics, 232, 425ā453, 1994a.
McBride, J.H., White, R.S., Henstock, T.J., and Hobbs, R.W., Complex structure along a Mesozoic seafloor spreading ridge: BIRPS deep seismic reflection, Cape Verde Abyssal Plain, 119,453ā478, 1994b.
Minshull, T.A., White, R.S., Mutter, J.C., Buhl, P., Detrick, R.S., Williams, C.A., and Morris, E., Crustal structure at the Blake Spur Fracture Zone from expanding spread profiles, J. Geophys. Res., 96, 9955ā9984, 1991.
Minshull, T.A., and Singh S.C., Shallow structure of oceanic crust in the Western North tlantic from seismic waveform inversion and modeling, J. Geophys. Res., 98, 1777ā1792, 1993.
Morris, E., Detrick, R.S., Minshull, T.A., Mutter, J.C., White, R.S., Su, W., and Buhl P., Seismic Structure of Oceanic Crust in the Western North Atlantic, 98, J. Geophys. Res., 98, 13879ā13903, 1993.
Mutter, J.C., Detrick, R.S., and North Atlantic Transect Study Group, Multichannel seismic evidence for anomaously thin crust at Blake Spur fracture zone, Geology, 12, 534537, 1984.
Mutter, J.C., and Karson, J.A., Structural processes at slow-spreading ridges, Science, 257, 627ā634, 1992.
NAT Study Group, North Atlantic Transect: A wide-aperture, two-ship multichannel seismic investigations of the ocean crust, J. Geophys. Res., 90, 10321ā10341, 1985.
Parkes, G.E., Hatton, L., and Haugland, T., Marine source array directivity: a new wide airgun array system, First Break, 2, 9ā15, 1984.
Roest, W.R., Danobeitia, J.J., Verhoef, J., and Collette, B.J., Magnetic anomalies in the Canary Basin and the Mesozoic evolution of the Central North Atlantic, Mar. Geophys. Res., 14, 1ā24, 1992.
Stolt, R.H., Migration by Fourier transform, Geophysics, 43, 23ā48, 1978.
Sundvik, M., Larson, R.L., and Detrick, R.S., Rough-smooth basement boundary in the western North Atlantic basin: Evidence for seafloor-spreading origin, Geology, 12, 31ā34, 1984.
Sundvik, M., and Larson, R.L., Seafloor spreading history of the western North Atlantic basin derived from Keathly Sequence and computer graphics, Tectonophysics., 155, 4971, 1988.
Toomey, D.R., Soloman, S.C. Purdy, G.M., Microearthquakes beneath the median valley of the Mid-Atlantic Ridge near 23Ā°N: Tomography and tectonics, J. Geophys. Res., 93, 9093ā9112, 1988.
Verhoef, J., Collette, B.J., DaƱobeitia, J.J., Roeser, H.A., and Roest, W.R., Magnetic anomalies off West Africa (20ā38Ā°N), Mar. Geophys. Res., 13, 81ā103, 1991.
White, R.S., McBride, J.H., Henstock, T.J., and Hobbs, R.W., Internal structure of a spreading segment of Mesozoic oceanic crust, Geology, 22, 597ā600, 1994.
White, R.S., Detrick, R.S., Mutter, J.C., Buhl, P., Minshull, T.A., and Morris, E., New seismic images of the crustal structure, Geology, 18, 462ā465, 1990.
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DaƱobeitia, J.J., Hobbs, R.W., McBride, J.H., Minshull, T.A., Gallart, J. (1995). Structure of Atlantic Oceanic Crust Around Chron M16 from Deep Seismic Reflection Profiles. In: Banda, E., TornƩ, M., Talwani, M. (eds) Rifted Ocean-Continent Boundaries. NATO ASI Series, vol 463. Springer, Dordrecht. https://doi.org/10.1007/978-94-011-0043-4_10
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DOI: https://doi.org/10.1007/978-94-011-0043-4_10
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