LITHOPROBE—southern Vancouver Island: Cenozoic subduction complex imaged by deep seismic reflections

1987 ◽  
Vol 24 (1) ◽  
pp. 31-51 ◽  
Author(s):  
R. M. Clowes ◽  
M. T. Brandon ◽  
A. G. Green ◽  
C. J. Yorath ◽  
A. Sutherland Brown ◽  
...  
Keyword(s):  
Large Scale ◽  
Sedimentary Rocks ◽  
Indirect Evidence ◽  
Vancouver Island ◽  
Late Eocene ◽  
San Juan ◽  
Juan De Fuca Plate ◽  
Reflective Layer ◽  
Juan De Fuca ◽  
Accreted Terranes

The LITHOPROBE seismic reflection project on Vancouver Island was designed to study the large-scale structure of several accreted terranes exposed on the island and to determine the geometry and structural characteristics of the subducting Juan de Fuca plate. In this paper, we interpret two LITHOPROBE profiles from southernmost Vancouver Island that were shot across three important terrane-bounding faults—Leech River, San Juan, and Survey Mountain—to determine their subsurface geometry and relationship to deeper structures associated with modem subduction.The structure beneath the island can be divided into an upper crustal region, consisting of several accreted terranes, and a deeper region that represents a landward extension of the modern offshore subduction complex. In the upper region, the Survey Mountain and Leech River faults are imaged as northeast-dipping thrusts that separate Wrangellia, a large Mesozoic–Paleozoic terrane, from two smaller accreted terranes: the Leech River schist, Mesozoic rocks that were metamorphosed in the Late Eocene; and the Metchosin Formation, a Lower Eocene basalt and gabbro unit. The Leech River fault, which was clearly imaged on both profiles, dips 35–45 °northeast and extends to about 10 km depth. The Survey Mountain fault lies parallel to and above the Leech River fault and extends to similar depths. The San Juan fault, the western continuation of the Survey Mountain fault, was not imaged, although indirect evidence suggests that it also is a thrust fault. These faults accommodated the Late Eocene amalgamation of the Leech River and Metchosin terranes along the southern perimeter of Wrangellia. Thereafter, these terranes acted as a relatively coherent lid for a younger subduction complex that has formed during the modem (40 Ma to present) convergent regime.Within this subduction complex, the LITHOPROBE profiles show three prominent bands of differing reflectivity that dip gently northeast. These bands represent regionally extensive layers lying beneath the lid of older accreted terranes. We interpret them as having formed by underplating of oceanic materials beneath the leading edge of an overriding continental place. The upper reflective layer can be projected updip to the south, where it is exposed in the Olympic Mountains as the Core rocks, an uplifted Cenozoic subduction complex composed dominantly of accreted marine sedimentary rocks. A middle zone of low reflectivity is not exposed at the surface, but results from an adjacent refraction survey indicate it is probably composed of relatively high velocity materials (~ 7.7 km/s). We consider two possibilities for the origin of this zone: (1) a detached slab of oceanic lithosphere accreted during an episodic tectonic event or (2) an imbricated package of mafic rocks derived by continuous accretion from the top of the subducting oceanic crust. The lower reflective layer is similar in reflection character to the upper layer and, therefore, is also interpreted as consisting dominantly of accreted marine sedimentary rocks. It represents the active zone of decoupling between the overriding and underthrusting plates and, thus, delimits present accretionary processes occurring directly above the descending Juan de Fuca plate. These results provide the first direct evidence for the process of subduction underplating or subcretion and illustrate a process that is probably important in the evolution and growth of continents.

Monitoring temporal change in conductivity in the central Vancouver Island region, an area with past large earthquakes

1992 ◽  
Vol 29 (4) ◽  
pp. 601-608 ◽  
Author(s):  
D. R. Auld ◽  
S. E. Dosso ◽  
D. W. Oldenburg ◽  
L. K. Law
Keyword(s):  
Temporal Change ◽  
Vancouver Island ◽  
Crust And Upper Mantle ◽  
Juan De Fuca Plate ◽  
Juan De Fuca ◽  
Elevation Changes ◽  
Robust Processing ◽  
Processing Techniques ◽  
Large Earthquakes

Two major earthquakes, magnitude 7.0 in 1918 and magnitude 7.3 in 1946, have occurred this century in the central region of Vancouver Island, British Columbia, Canada. Levelling data in the region indicate relative uplift of 4 mm/year from 1977 to 1984, followed by subsidence at approximately the same rate over the next 2 years. In response to the observed elevation changes, a program was initiated to investigate if temporal changes in the geoelectrical conductivity might be associated with earthquake occurrence. Beginning in 1986, magnetotelluric (MT) data have been measured annually at a number of sites on central Vancouver Island to monitor the long-term variability of the conductivity of the crust and upper mantle in the region. Robust processing techniques now used in the analysis of MT data enhance the possibility of detecting changes in the conductivity.Past studies involving the monitoring of MT stations have considered temporal change only in terms of the measured responses. However, formulating the inverse problem of constructing conductivity–depth models that vary minimally from year to year allows quantitative investigation of the changes required in the models to accommodate the yearly variations in the data. This provides a method of evaluating the processes and depths involved in observed changes in the data. Our modelling study indicates a small but systematic yearly decrease in conductivity from 1987 to 1990 localized in a conductive zone overlying the subducting Juan de Fuca Plate.

Jurassic–Cretaceous rock units along the southern edge of the Wrangellia terrane on Vancouver Island

1985 ◽  
Vol 22 (8) ◽  
pp. 1223-1232 ◽  
Author(s):  
Margaret E. Rusmore ◽  
Darrel S. Cowan
Keyword(s):  
High Pressure ◽  
Upper Jurassic ◽  
Vancouver Island ◽  
Late Eocene ◽  
San Juan ◽  
Tectonic Event ◽  
Cretaceous Rock ◽  
Early Oligocene ◽  
Southern Margin ◽  
Wrangellia Terrane

Rocks formerly mapped as Leech River Formation can be subdivided into two partly coeval rock units with completely different histories. The Upper Jurassic – Lower(?) Cretaceous Pandora Peak unit, which comprises black mudstone, terrigenous greywacke, radiolarian ribbon chert, green tuff, metabasaltic greenstone, minor pebbly mudstone, and a few blocks of limestone, was probably deposited in small basins on a continental margin. Local stratal disruption occurred before sediments were lithified. A static, high-pressure, low-temperature metamorphism produced lawsonite-bearing assemblages in metaclastic rocks. The Pandora Peak unit was originally coextensive with the Pacific Rim complex on western Vancouver Island and the Constitution formation in the San Juan Islands of Washington. The Leech River complex consists of foliated metasandstone, phyllite, and minor metabasalt of probable Jurassic–Cretaceous age. Multiple folding, transposition, and synkinematic greenschist- to amphibolite-facies metamorphism culminated about 40 Ma.The Pandora Peak unit is separated from crystalline rocks of the Wrangellia terrane by major faults. In southeast Victoria, partly retrograded amphibolites of the Wark–Colquitz complex overlie locally cataclastic lawsonite-bearing Pandora Peak rocks along the newly discovered Trial Islands thrust. A similar thrust separates the two units in Finlayson Arm, but near Port Renfrew the Pandora Peak terrane and crystalline West Coast complex are juxtaposed along the high-angle San Juan Fault. In each of these areas, emplacement of the Pandora Peak unit postdated the high-pressure (lawsonite-grade) metamorphism, which occurred between late Albian – early Cenomanian and Santonian–Campanian time (approximately 99–83 Ma). The Pandora Peak terrane was emplaced during a major Late Cretaceous or early Tertiary tectonic event that modified and probably truncated the southern margin of the Wrangellia terrane. Following this event the Leech River complex was faulted against the southern margin of the Pandora Peak terrane near Port Renfrew and in Goldstream Park in the Late Eocene or Early Oligocene.

Biostratigraphic, strontium isotopic, and geologic constraints on the landward movement and fragmentation of terranes within the Tofino Basin, British Columbia

2012 ◽  
Vol 49 (7) ◽  
pp. 819-856 ◽  
Author(s):  
Marjorie J. Johns ◽  
Julie A. Trotter ◽  
Christopher R. Barnes ◽  
Y. Roshni Narayan
Keyword(s):  
Late Eocene ◽  
Pacific Rim ◽  
Magnetic Data ◽  
Juan De Fuca Plate ◽  
Early Oligocene ◽  
The Pacific ◽  
Juan De Fuca ◽  
History Of ◽  
Oceanic Sediment ◽  
Middle Pliocene

Significant advancements in understanding the complex evolution of the Tofino Basin at a convergent accretionary margin are enabled by combining contextual geologic information with new isotopic and paleontological data. A high-resolution Cenozoic chronostratigraphy of the basin is constrained by strontium isotope ages (36.9–1.3 Ma) of Late Eocene to Pleistocene foraminifers together with a revised biostratigraphy (foraminifers and ichthyoliths) from six offshore wells and outcrop samples, new specimen thermal alteration values, and existing well log data. These data are integrated with archival multichannel seismic and magnetic data to interpret offshore well positions with relation to sub-basins and structural highs of the Pacific Rim and Crescent terranes, and other accreted strata. Six regions of the Tofino Basin are defined based on structure and depositional differences during the Eocene to Holocene history of accretion and fragmentation of the Crescent terrane and it underthrusting the Pacific Rim terrane. Subsequent oceanic sediment accretions and deposition of overlying sediments up to about 4000 m thick resulted as the Juan de Fuca plate subducted beneath Vancouver Island. Observations include different fragmentations and landward movements of the Crescent and Pacific Rim terranes in the regions and two fault styles in the Ucluelet and Carmanah regions where six new sub-basins are defined. Results, especially for the Ucluelet and Carmanah sub-basins, indicate periods of deformation during the Late Eocene, Late Oligocene, Middle–Late Miocene, and post middle Pliocene, whereas the Early Oligocene and Early Miocene had periods of relatively slow and less disturbed deposition.

A magnetotelluric sounding across Vancouver Island detects the subducting Juan de Fuca plate

Nature ◽  
1986 ◽  
Vol 321 (6070) ◽  
pp. 596-599 ◽  
Author(s):  
R. D. Kurtz ◽  
J. M. DeLaurier ◽  
J. C. Gupta
Keyword(s):  
Vancouver Island ◽  
Magnetotelluric Sounding ◽  
Juan De Fuca Plate ◽  
Juan De Fuca

Neodymium–strontium–lead isotopic study of Vancouver Island igneous rocks

1991 ◽  
Vol 28 (11) ◽  
pp. 1744-1752 ◽  
Author(s):  
A. Andrew ◽  
R. L. Armstrong ◽  
D. Runkle
Keyword(s):  
Mantle Source ◽  
Large Scale ◽  
Crustal Contamination ◽  
Vancouver Island ◽  
Isotopic Signature ◽  
Late Eocene ◽  
Crustal Material ◽  
Isotopic Data ◽  
Isotopic Study ◽  
Depleted Mantle

Combined neodymium, strontium, and lead isotope measurements show that Vancouver Island is made up of Phanerozoic crustal material accreted to North America in the Mesozoic and early Cenozoic, but that there are differences in the relative proportions of depleted mantle and aged, enriched crustal components in the Phanerozoic magmatic episodes that contribute to this new crust.The Devonian Sicker Group volcanic arc has an isotopic signature that can be explained by mixing mantle material with subducted continentally derived sediments. The Early to Middle Jurassic Bonanza Volcanics and Island Intrusions magmatic arc isotopic signature indicates mixing of magma from a depleted mantle source with crustal material of Sicker arc-type, rather than of continental origin. This is consistent with large-scale assimilation of Sicker Group and Karmutsen rocks by Jurassic mantle-derived magmas, or introduction of arc-derived sediments into the Jurassic mantle by subduction. Eocene calc-alkaline Flores Volcanics – Catface Intrusions may be derived from reworked Vancouver Island crust with little addition of mantle material.Late Triassic Karmutsen Formation flood basalts are similar to the lower parts of the Columbia River Basalt in all three isotope systems and in petrochemistry. Radiogenic isotopic data are consistent with the interpretation that the Karmutsen basalts were extruded in a post-arc or back-arc setting, with mantle lithosphere and depleted mantle components, and perhaps some plume source input and crustal contamination, but the latter are not provable from the radiogenic isotopic data alone.Early Eocene Metchosin basalts show a depleted mantle source, consistent with their origin as ocean islands, before Middle to Late Eocene accretion to the rest of Vancouver Island.

Lithoprobe, southern Vancouver Island: Seismic reflection sees through Wrangellia to the Juan de Fuca plate

Geology ◽  
1985 ◽  
Vol 13 (11) ◽  
pp. 759 ◽  
Author(s):  
C. J. Yorath ◽  
A. G. Green ◽  
R. M. Clowes ◽  
A. Sutherland Brown ◽  
M. T. Brandon ◽  
...  
Keyword(s):  
Seismic Reflection ◽  
Vancouver Island ◽  
Juan De Fuca Plate ◽  
Juan De Fuca

Structure and Tectonics of the Continental Slope West of Southern Vancouver Island

1974 ◽  
Vol 11 (9) ◽  
pp. 1187-1199 ◽  
Author(s):  
Sandra M. Barr
Keyword(s):  
Continental Slope ◽  
Vancouver Island ◽  
Juan De Fuca Ridge ◽  
Spreading Center ◽  
Source Depth ◽  
Northern Margin ◽  
Juan De Fuca Plate ◽  
Juan De Fuca ◽  
Diffuse Zone ◽  
Oceanic Basement

The lower continental slope west of southern Vancouver Island consists of a series of ridges formed by folding, faulting, and uplift of Cascadia Basin deposits; underlying oceanic basement, at least initially, is not involved in this deformation. The middle and upper continental slope has probably formed by the same process, combined with deposition of overlying material coming directly from the continent. This compressive deformation is postulated to be a result of underthrusting of the America Plate by the Juan de Fuca Plate. Linear magnetic anomalies produced at the Juan de Fuca spreading center can be traced under the slope for at least 40 km, further evidence for underthrusting. Anomaly source depth calculations indicate that oceanic basement dips beneath the continental slope at an angle of more than 10°. A diffuse zone of earthquake epicenters extending northeast from the northern tip of Juan de Fuca Ridge may mark the present northern margin of the Juan de Fuca Plate.

Crustal structure of the Cascadia subduction zone, southwestern British Columbia, from potential field and seismic studies

1997 ◽  
Vol 34 (3) ◽  
pp. 317-335 ◽  
Author(s):  
Ron M. Clowes ◽  
David J. Baird ◽  
Sonya A. Dehler
Keyword(s):  
Subduction Zone ◽  
Potential Field ◽  
Vancouver Island ◽  
Strike Slip ◽  
High Density ◽  
Pacific Rim ◽  
Cascadia Subduction Zone ◽  
Crustal Material ◽  
Juan De Fuca Plate ◽  
Juan De Fuca

The northern Cascadia subduction zone is a region of convergence between the oceanic Explorer and northern Juan de Fuca plates and the continental North American plate. Potential field and new seismic reflection data coupled with previous seismic results and geology enable derivation of a series of density – magnetic susceptibility cross sections and a block density model from the ocean basin to the volcanic arc from 2.5- and 3-dimensional interpretations. The lateral extent and thickness of the accreted wedge vary significantly along the zone. The narrow, metasedimentary Pacific Rim terrane lies immediately west of Wrangellia and extends the length of Vancouver Island, consistent with its emplacement by strike-slip faulting following the accretion of Wrangellia. The ophiolitic Crescent terrane is a narrow slice lying seaward of the Pacific Rim terrane but not extending northward beyond the Juan de Fuca plate. In this region, the Crescent terrane was emplaced in a strike-slip or obliquely convergent style during the latter stages of emplacement of Pacific Rim terrane. Below the accreted terranes, the Explorer plate is shallower than Juan de Fuca plate, resulting in a thinner crust. High-density lower crustal material lies beneath the western edge of Vancouver Island, supporting interpretations of wide-scale underplating of Wrangellia. The shape of the boundary region between Wrangellia and the Coast belt to the east varies along strike and may be controlled by properties of preexisting plutonic rocks. The low-density Coast belt plutons extend throughout most of the crust and are underlain by a lowermost crustal high-density layer, which may be indicative of fractionation accompanying magma generation.

The Vancouver Island Seismic Project: a co-CRUST onshore–offshore study of a convergent margin

1983 ◽  
Vol 20 (5) ◽  
pp. 719-741 ◽  
Author(s):  
R. M. Ellis ◽  
G. D. Spence ◽  
R. M. Clowes ◽  
D. A. Waldron ◽  
I. F. Jones ◽  
...  
Keyword(s):  
Velocity Structure ◽  
Deep Ocean ◽  
Crustal Thickness ◽  
Vancouver Island ◽  
Seismic Structure ◽  
Secondary Phases ◽  
Juan De Fuca Plate ◽  
Deep Crust ◽  
Air Gun ◽  
Juan De Fuca

The seismic structure of the British Columbia continental margin has been investigated using four reversed refraction profiles. The profile across strike extended 350 km from the volcanic arc on the continent to the deep ocean of the Juan de Fuca Plate; the three profiles along strike were located on Vancouver Island, on the continental shelf, and in the deep ocean on the Juan de Fuca Plate. Interpretation of the profile along Vancouver Island yields a well constrained model for the upper crust with velocity increasing from ~5.3 km/s at the surface to ~6.4 km/s at 2 km depth to ~6.75 km/s at 15.5 km depth where the velocity increases sharply to ~7 km/s. The velocity structure of the deep crust and the crustal thickness are poorly constrained. Four possible velocity functions, based on ambiguous first arrivals and (or) secondary phases interpreted as Moho reflections, are presented. The preferred one includes a deep crustal low velocity zone with a crustal thickness of 37 km; models with a constant 7.1 km/s deep crust require thicknesses of 52 km. Preliminary results from the profile across strike show the dip of the basement towards the continent steepens from approximately 1.4° immediately west of the continental rise to ~4° beneath the rise. Sediment velocities increase as the sedimentary layer thickens towards the shelf. The Moho, with velocity near 8 km/s, appears to dip at similar angles in this region; the dip is ~6° from the edge of the shelf to the central portion of Vancouver Island; here there is an abrupt thickening of the continental crust by about 10 km with a flat-lying Moho to the east. This suggests a contact between subducting oceanic Moho and continental Moho. A small positive velocity gradient is required in the mantle.Two short reflection lines, one using explosives and the other a large air gun fired in an inlet, were recorded on a land-based multichannel reflection system. These were run to test the feasibility of obtaining coherent reflections to upper mantle depths in this complex geological environment, and of acquiring deep reflection data in coastal areas with an air-gun source. The preliminary explosion section showed reflections near 4.4 and 6.8 s. The depths of these reflections correspond closely to the 15.5 km crustal refractor and the top of the subducting oceanic lithosphere, respectively. Dip on the deeper reflector is close to that estimated from the refraction profile. Without stacking or velocity filtering, the air-gun recordings on a line adjacent to the explosion profile show arrivals of energy at similar times.

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