Abstract
During July and August 1991, the French-American Blanconaute dive program used the French submersibleNautile to investigate the West Blanco Depression (WBD), a deep, elongate trough located at the intersection of the Blanco Transform Fault Zone with the southern Juan de Fuca Ridge (JdFR). Twenty dives were carried out along the north wall of the WBD, which exposes the upper oceanic crust over a 65 km distance, from the JdFR axis (to the west) to the oblique trace of an ancient propagator (to the east, crustal age around 2 Ma). Thirteen of these dives were precisely located within a 13 × 7 km zone of the north wall, covered by a high-resolution sonar mapping operation during the Blancotrough cruise in 1987. This series of geological traverses, plus 4 dives across the south wall of the WBD (one dive) and the adjacent Parks Plateau (3 dives), collected 242 rock samples. We report here the main results of the dive program and preliminary laboratory studies:
-
1.
Transform-related tectonic activity has recently abandoned the southern margin of Parks Plateau, and is presently located inside the WBD area, mainly along its northern wall. The tectonic features observed are compatible with a right-lateral strike-slip system, with a NE-SW extensional component.
-
2.
Three main lithological units are exposed along the north wall of the WBD. From top to bottom, they are: (1) a Volcanic Unit, forming a steep upper cliff, made of massive and pillow flows and basaltic dikes, with an estimated average thickness of 800 m; (2) a less steep Transition Zone, about 150 to 400 m thick, largely masked by rubble but exposing both diabase outcrops and pillow flows; and (3) a massive Diabase Unit, exposed over 700–800 m, with a dike complex structure visible from place to place, and cut by a net of hydrothermal veins. Deep crustal rocks such as gabbros were not observed.
-
3.
Spectacular mass-wasting features are visible all along the north wall of the WBD. About 60% of the face of the wall is masked by talus cones, rubble, rock avalanche deposits and slide blocks. Three main landslides, of approximately one km3 in volume each, were tentatively identified. One of them was mapped in detail and consists of an approximately 300 m thick (0.85 km3), coherent slide block detached from a zone where intense hydrothermal alteration and faulting have obviously weakened the bedrock, that is in places entirely altered to blue clays.
-
4.
The basaltic lavas of the WBD north wall show a remarkable evolution with time, from east to west. Around the tip of the ancient propagator, they are restricted to primitive, olivine-rich picritic basalts. Proceeding westward, they exhibit a wide range of differentiation, including highly fractionated, FeTi-rich ferrobasalts at about 35–45 km from the JdFR axis. When approaching the JdFR axis, the FeTi enrichment decreases gradually, and the ferrobasalts evolve towards slightly differentiated MORB-type basalts, typical of the southern JdFR. This magmatic evolution marks the transition from the end of a propagating rift regime to a steady-state accretion regime.
-
5.
The WBD north wall also permits the study of weathering and hydrothermal alteration processes and their evolution in space and time. Vertically, the alteration products evolve from oceanic weathering and zeolite facies (Volcanic Unit) to the greenschist facies (Transition Zone and Diabase Unit). Horizontally, the evolution with time is mainly a general hydration of the crust that is, however, very irregularly distributed.
-
6.
Several vertical magnetic traverses along the north wall of the WBD, using a bottom magnetometer attached to the basket of the submersible, have shown a sharp 5000 to 7000 nT positive anomaly at about 3500 m depth. This anomaly corresponds exactly to the first appearance of extrusive pillow-lava outcrops, and confirms the dramatic decrease in magnetic anomaly amplitude below that depth, detected during the Blancotrough cruise in 1987. The vertical magnetic profiles thus appear to have imaged the base of the magnetic source layer.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Alt, J. F. and Honnorez, J., 1984, Alteration of the upper oceanic crust, DSDP site 417: Mineralogy and chemistry,J. Geophys. Res. 87, 149–169.
Alt, J. F., Honnorez, J., Laverne, C. and Emmermann, R., 1986, Hydrothermal alteration of a 1 km section through the upper oceanic crust, deep sea drilling project hole 504B: Mineralogy, chemistry, and evolution of seawater-basalt interactions,J. Geophys. Res. 91, 10309–10335.
Anderson, R. N., Honnorez, J., Becker, K., Adamson, A. C., Alt, J. C., Emmermann, R., Kempton, P. D., Kinoshita, H., Laverne, C., Mottl, M. J. and Newmark, R. L., 1982, DSDP Hole 504B: The first reference section over 1 km through Layer 2 of the oceanic crust,Nature 300, 589–594.
Atwater, T. and MacDonald, K. C., 1977, Are spreading centers perpendicular to their transform faults?,Nature 270, 715–719.
Aumento, F. and Loubat, H., 1971, The Mid Atlantic Ridge near 45°N. Serpentinized ultramafic intrusions,Can. J. Earth Sci. 8, 631–663.
Barton, N. and Choubey, V., 1977, The shear strength of rock joints in theory and practice,Rock Mechanics 10, 1–54.
Ben Avraham, Z., 1985, Structural framework of Elat (Aqaba), northern red sea,J. Geophys. Res. 90, 703–726.
Ben Avraham, Z. and Zoback, M. D., 1992, Transform-normal extension and asymmetric basins: An alternative to pull-apart models,Geology 20, 423–426.
Blanconaute Shipboard Party, 1991. The western Blanco Transform: Preliminary insights into the oceanic crustal architecture and transform zone processes,E.O.S. Trans. AGU,72, 519.
Bonatti, E., Honnorez, J., and Ferrara, G., 1971, Ultramafic rocks, peridotite gabbro-basalt complex from the equatorial Mid-Atlantic Ridge,Phil. Trans. Roy. Soc. Lond. A. 268, 385–402.
Bonatti, E., Honnorez, J., Kirst, P., and Radicati, P., 1975, Contact-hydrothermal-dynamic metamorphism beneath the axial valley,J. Geol. 83, 61–78.
Bonatti, E. and Harrison, C. G. A., 1988, Eruption styles of basalt in oceanic spreading ridges and seamounts: effect of magma temperature and viscosity,J. Geophys. Res. 93, 2967–2980.
Byerly, G., 1980, The nature of differentiation trends in some volcanic rocks from the Galapagos spreading center,J. Geophys. Res. 85, 3797–3810.
Carson, M. A. and Kirkby, M. J., 1972,Hillslope Form and Process: Cambridge University Press, Cambridge, England, 473 pp.
Christie, D. M. and Sinton, J. M., 1981, Evolution of abyssal lavas along propagating segments of the Galapagos spreading center,Earth Planet. Sci. Lett. 56, 321–335.
Coleman, J. M. and Prior, D. B., 1988, Mass wasting on continental margins,Ann. Rev. Earth Planet. Sci. 16, 101–119.
Dauteuil, O., 1995, Fault pattern from Seabeam processing: the western part of the Blanco Fracture Zone (NE Pacific),Mar. Geophys. Res. 17 17–35.
Delaney, J. R., Johnson, H. P. and Karsten, J. L., 1981, The Juan de Fuca Ridge-hot spot-propagating rift system: New tectonic, geochemical, and magnetic data,J. Geophys. Res. 86, 11,747–11,750.
Delaney, J. R., Spiess, F. N., Colony, W. E., Karsten, J. L., Kelley, D. E. and Nehlig, P., 1987, A complete Deep-Tow swath map of south-facing “wall” of the Blanco Trough, Juan de Fuca Region,Trans. Am. Geophys. Un. 68, 1402.
Dziak, R. P., Fox, C. G. and Embley, R. W., 1991, Relationship between the seismicity and geologic structure of the Blanco Transform Fault Zone,Mar. Geophys. Res. 13, 203–208.
Eaby, J., Clagues, D. A. and Eissen, J. P., 1986, Gabbroic Xenoliths and Host Ferrobasalts from the Southern Juan de Fuca,J. Geophys. Res. 91, 3795–3820.
Elvers, D., Srivastava, S. P., Potter, K., Morly, J., and Solidel, D., 1973, Asymmetric spreading across the Juan de Fuca and Gordia Rises as obtain from a detailed magnetic survey,Earth Planet. Sci. Lett. 20, 211–219.
Embley, R. W., 1985, A locally formed deep-ocean canyon system along the Blanco Transform,Geo. Marine Lett. 5, 99–104.
Embley, R. W., Kulm, L. D., Massoth, G., Abbott, D. and Holmes, M., 1986, Morphology, Structure, and Resource Potential of the Blanco Transform Fault Zone. In: Scholl, D. W., Grantz, A. and Vedder, J. G., (eds.).Geology and Resource Potential of the Continental Margin of Western North America and Adjacent Ocean Basins — Beaufort Sea to Baja, California,vol 6, Circum-Pacific Council for Energy and Mineral Resources, Earth Science Series, 549–561.
Embley, R. W. and Wilson, D. S., 1992, Morphology of the Blanco transform fault zone N-E Pacific: implication for its tectonic evolution,Mar. Geophys. Res. 14, 25–45.
Fornari, D. J., Perfit, M. R., Malahoff, A. and Embley, R., 1983, Geochemical studies of abyssal lavas recovered by DSRV Alvin. from eastern Galapagos Rift, Inca Transform, and Ecuador Rift. 1. Major element variations in natural glasses and spacial distribution of lavas,J. Geophys. Res. 88, 10,519–10,529.
Francheteau, J., Choukroune, P., Hekinian, R., Le Pichon, X. and Needham, H. D., 1976, Oceanic fracture zones do not provide deep sections of the crust,Can. J. Earth Sci. 13, 1223–1235.
Francheteau, J., Armijo, R., Cheminee, J. L., Hekinian, R., Lonsdale, P. and Blum, N., 1992, Dyke complex of the East Pacific Rise exposed in the walls of Hess Deep and the structure of the upper oceanic crust,Earth Planet. Sci. Lett. 111, 109–121.
Gillis, K. M. and Robinson, P. T., 1990, Patterns and processes of alteration in the lavas and dikes of the Troodos Ophiolite, Cyprus,J. Geophys. Res. 95, 21,523–21,548.
Hekinian, R., Bideau, D., Cannat, M., Francheteau, J. and Hébert R., 1992, Volcanic activity and crust-mantle exposure in the ultrafast Garrett Transform Fault, near 13°18′S. in the Pacific,Earth Planet. Sci. Letters 108, 259–275.
Hey, R. N., Duennebier, F. K., and Morgan, W. J., 1980, Propagating rifts on Mid Ocean Ridges,J. Geophys. Res. 85, 2647–2658.
Hey, R. N. and Wilson, D. S., 1982, Propagating rift explanation for the tectonic evolution of the northeast Pacific — The pseudomovie,Earth Planet. Sci. Lett. 58, 167–188.
Holmes, M. L., Gardner, J. V., Johnson, H., Campbell, J. F., Carlson, P., Edwards, B. and Karl, H., 1984, SeaMARC II studies of the Juan de Fuca and Gorda Ridges,Trans. Am. Geophys. Un. 65, 279.
Jaeger, J. C., 1971, Friction of rocks and stability of rock slopes,Geotechnique 21, 97–134.
Juteau, T., Bideau, D., Dauteuil, O., Manac'h, G., Naïdoo, D., Nehlig, P., Ondreas, H., Tivey, M. and Whipple, K., 1993, The western Blanco Trough: lithology, tectonics and magnetic structure of a young oceanic crust,TERRA. EUG VII, 194.
Karson, J. A. and Dick, H. J. B., 1983, Tectonics of ridge-transform intersections at the Kane fracture zone,Mar. Geophys. Res. 6, 51–98.
Karson, J. A., Hurst, S. D. and Lonsdale P., 1992, Tectonic rotations of dikes in fast-spread oceanic crust exposed near Hess Deep,Geology 20, 685–688.
Laverne, C., 1987,Les altérations des basaltes en domaine océanique: Minéralogie, pétrologie et géochimie d'un système hydrothermal: la puits 504B, Pacifique oriental Thèse 3ième cycle, Aix Marseille, (France).
Lippard, S. J., Shelton, A. W. and Gass, I. G., 1986,The Ophiolite of the northern Oman. Memoir n°11, The Geological Society, Blackwell Scientific Publ., Oxford, United Kingdom.
Manac'h, G., Bideau, D., Juteau, T. and Naïdoo, D., 1993, The Western Blanco Trough: Petrology of the northern wall between 0 Ma and 1.5 Ma,TERRA. EUG VII, 196.
Melson, W. G., and Van Andel, T. H., 1966, Metamorphism in the Mid-Atlantic Ridge, 22° N lat,Mar. Geophys. Res. 4, 165–186.
Melson, W. G., and Thompson, G., 1971, Petrology of a transform zone and adjacent ridge segments,Phil. Trans. Roy. Soc. Lond. A. 268, 423–441.
Miyashiro, A., Shido, F. and Ewing, M., 1969, Crystallisation and differentiation in abyssal tholeiites and gabbros from Ocean ridges,Earth. Planet. Sci. Lett. 7, 361–365.
OTTER, 1984, The geology of the Oceanographer Transform: the ridge-transform intersection,Mar. Geophys. Res. 6, 109–141.
OTTER, 1985, The geology of the Oceanographer Transform: The transform domain,Mar. Geophys. Res. 7, 329–358.
Parker, R. L., and Huestis, S. P., 1974, The inversion of magnetic anomalies in the presence of topography,J. Geophys. Res. 79, 1587–1593.
Perfit, M. R., and Heezen, B. C., 1978, The geology and evolution of the Cayman Trench,Geol. Soc. Amer. Bull. 89, 1155–1174.
Perfit, M. R. and Fornari, D. J., 1983a, Geochemical studies of abyssal lavas recovered by Alvin from eastern Galapagos Rift, Inca Transform, and Ecuador Rift. 2. Phase chemistry and crystallisation history,J. Geophys. Res. 88, 10,530–10,550.
Perfit, M. R. and Fornari, D. J., 1983b, Geochemical studies of abyssal lavas recovered by Alvin from eastern Galapagos Rift, Inca Transform, and Ecuador Rift. 3. Trace element abundances and petrogenesis,J. Geophys. Res. 88, 10,551–10,572.
Press, W. H., Flannery, B. P., Teukolsky, S. A., and Vertterling, W. T., 1986, Numerical recipes: The art of scientific computing, Cambridge University Press, Cambridge, UK, 818 pp.
Rabu, D., Nehlig, P., Rogers, J.,et al., 1993, Stratigraphy and structure of Oman Mountains,Doc. B.R.G.M.,221, 262 pp.
Raff, A. D. and Mason, P. G., 1961, Magnetic survey off the west coast of North America, 40°N latitude to 52°N latitude.,Geol. Soc. Am. Bull. 72, 1267–1270.
Ramsay, J. G., 1980, The Crack-Seal mechanism of rock deformation,Nature 284, 135–139.
Riddihough, R. P., 1984, Recent movement of the Juan de Fuca plate system.,J. Geophys. Res. 89, 6980–6995.
Selby, M. J., 1982, Controls on the stability and inclinations of hillslopes and hard rocks,Earth Surface Processes and Landforms 7, 449–467.
Sinton, J. M., Wilson, D. S., Christie, D. M., Hey, R. N. and Delaney, J. R., 1983, Petrologic consequences of rift propagation on oceanic spreading ridges.,Earth Planet. Sci. Lett. 62, 193–207.
Sinton, J. M. and Detrick, R. S., 1992, Mid-Ocean Ridge magma chambers,J. Geophys. Res. 97, 197–216.
Smith, G. M., 1985, Source of marine magnetic anomalies: Some results from DSDP Leg 83,Geology 13, 162–165.
Speiss, F. N. and Lonsdale, P., 1983, Deep Tow rise crest exploration techniques,Mar. Technol. Soc. Jour. 16, 193–207.
Spence, W., 1989, Stress origins and earthquakes potential in Cascadia,J. Geophys. Res. 94, 3076–3088.
Stroup, J. B. and Fox, P. J., 1981, Geologic investigations in the Cayman Trough: Evidence for thin oceanic crust along the Mid-Cayman Rise,J. Geol. 89, 395–420.
Sun, S. S. and McDonough, W. F., 1989, Chemical and isotopic systematics of oceanic basalts: implications for mantle composition and processes, in: Saunders A. D. & Norry M. J. (eds.), Magmatism in the Ocean Basins,Geological Society Special Publication,42, 313–345.
Terzaghi, K., 1962, Stability of steep slopes in hard unweathered rock,Geotechnique 12, 251–270.
Vine, F. J., 1968, Magnetic anomalies associated with the mid-ocean ridges, in: R. A. Phinney (Princeton Univ. Press) (ed).,The History of the Earth's Crust, 73 pp.
Whipple, K. X., and Naidoo, D. D., 1991, Mass wasting in the transform fault environment,EOS Trans. AGU. 72, 519.
Wilson, D. S., Hey, R. N. and Nishimura, C., 1984, Propagation as a mechanism of reorientation of Juan de Fuca Ridge,J. Geophys. Res. 89, 9215–9225.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Juteau, T., Bideau, D., Dauteuil, O. et al. A submersible study in the western Blanco fracture Zone, N.E. Pacific: Structure and evolution during the last 1.6 Ma. Mar Geophys Res 17, 399–430 (1995). https://doi.org/10.1007/BF01371786
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF01371786