Leech River Fault
The Leech River Fault extends across the southern tip of Vancouver Island in British Columbia, Canada, creating the distinctively straight, narrow, and steep-sided valley occupied by Loss Creek and two reservoirs that runs from Sombrio Point (southeast of Port Renfrew) due east to the Leech River, and then turns southeast to run past Victoria. It is a thrust fault that marks the northernmost exposure of the Crescent terrane (part of Siletzia), where basalt of the Metchosin Igneous Complex (correlative with the Crescent Formation on the Olympic Peninsula) is dragged under Vancouver Island by the subducting Juan de Fuca Plate. About ten kilometers north the nearly parallel San Juan Fault marks the southern limit of rock of the Wrangellia terrane, which underlies most of Vancouver Island. Between these two northeast-dipping thrust faults are the Leech River Complex and (near Port Renfrew, but also outcrops near Victoria) the Pandora Peak Unit.[3] These, along with the Pacific Rim Complex further up the coast,[4] are remnants of the Pacific Rim terrane which was crushed between Wrangellia and Siletzia.[5] The contact between the bottom of Wrangellia and the top of the subducted PRT continues northwest along the coast as the West Coast Fault, and southeast towards Victoria as the Survey Mountain Fault. The Leach River Fault (LRF) extends off-shore towards Cape Flattery, where the Crescent—Pacific Rim contact continues northwest as the Tofino Fault (TF).[6]
The bottom contact of the Crescent Terrane has been uplifted and exposed along the edge of the Olympic Peninsula, where it is known as the Hurricane Ridge Fault (HRF). West of Cape Flattery the southern-most edge of the Crescent Terrane appears to be an extension of the LRF, suggesting left-lateral strike-slip along the Leech River Fault that has offset the Crescent Terrane nearly its whole width.[7]
The Leech River Fault (LRF) is a key element in understanding regional tectonic history as it and the San Juan Fault mark a change from the relatively simply subduction zone structure to the northwest, to the complex structures of the San Juan Islands and the Puget Lowland to the east and southeast. The straightness of its surface trace suggests the LRF has been a strike-slip fault.[8] In these respects the LRF is very similar to the Devils Mountain Fault, which can be traced due west from near Mount Vernon to a point just south of Victoria.[9]
Near the Leech River, where the Survey Mountain fault marks the eastern limit of the Leech River Complex,[10] the LRF and the lineament it follows make a sharp turn to the south (heading S70°E) to run down the Goldstream River, past Victoria and into the Juan de Fuca Strait.[11] Such sharp turns are geometrically impossible for individual strike-slip faults, but the southeast-striking Goldstream arm of the LRF parallels the cross-cutting Survey Mountain fault. Strong aeromagnetic anomalies in the Strait that curve from Victoria to Discovery Bay (west of Port Townsend) led to early speculation that the LRF, and the eastern limit of the Crescent Formation, ran down Discovery Bay and the west side of Puget Sound, following the edge of a relict continental margin just as the Tofino Fault follows the present margin.[12] More recent interpretations of marine seismic reflection studies align the Goldstream arm of the LRF with the Southern Whidbey Island Fault (SWIF), with splays branching towards Discovery Bay.[13]
Discovery of Crescent Formation basalt in an exploration well on Whidbey Island (just east of Port Townsend) has led some writers to locate this extension of the LRF onto the southern part of Whidbey Island, just where the SWIF is found.[14] While the eastern contact of the Crescent Formation is believed to not extend east Whidbey Island, and may double-back westward under Seattle,[15] active faulting on the SWIF extends southeast to where it connects with the Rattlesnake Mountain Fault Zone. Thus it appears that the Leech River and Devils Mountain faults were once a single left-lateral oblique fault (having both horizontal strike-slip and vertical dip-slip motion) that has been offset by right-lateral motion along the extended Survey Mountain—Southern Whidbey Island Fault.
The earlier history of the LRF is revealed by certain metamorphic rocks of the Pacific Rim terrane with a very distinctive mix of minerals.[16] These are also found in the San Juan Islands and in isolated outcrops spread across the Cascades. They formed between 100 and 84 Ma (millions of years ago) during the Late Cretaceous when the Pacific Rim terrane was crushed between Wrangellia and the North American continent, dismembered, and the pieces smeared along what was then the edge of the continent.[17] Continued right-lateral transpression carried outlying portions of Wrangellia and likely some odd pieces of the Pacific Rim terrane northwest to Gulf of Alaska.[18] Note that the ancient continental margin was not along the modern coast line (that runs due south from Vancouver Island), but turned in at the modern day Juan de Fuca Strait and followed the Olympic-Wallowa Lineament (OWL) towards southern Idaho,[19] paralleling the general trend of faulting in British Columbia and the North Cascades.
About 50 million years ago the Siletzia terrane, being borne to the northeast by the subducting plate, refused to be subducted. It ran it into the edge of the continent and embayed the overlying crust, bending the section of the Wrangellia—Pacific Rim contact now known as the San Juan fault to its current easterly orientation. This also initiated the oblique left-lateral Devils Mountain fault, including the section now known as the Leech River fault, and its right-lateral extension, the Darrington fault, that strikes southward from the town of Darrington to converge with the right-lateral strike-slip Straight Creek Fault at the OWL (see map).[20] About 42 million years ago this northeastward force rotated to a northerly direction which, striking the SWIF more obliquely, caused the strike-slip movement that offset the LRF past Victoria.
Undisturbed glacial deposits show that the Leech River fault has not been active since the last glaciation.[21] Accommodation of displacements on the Devils Mountain fault appears to be through fault zones in the San Juan Islands.[22]
See also
- Geoscape Victoria Poster with maps and a physiographic view of the fault.[23]
Notes
- ↑ Clowes et al. 1987, p. 35.
- ↑ Hayward et al. 2006, fig. 2.
- ↑ The principal authority for the Leech River Fault is Fairchild (1979), summarized in Fairchild & Cowan (1982).
- ↑ Exposed between Tofino and Barkley Sound.
- ↑ Groome et al. 2003, p. 328.
- ↑ Brandon 1989c, figure 12, p. 1132.
- ↑ Fairchild 1979, fig. 44b.
- ↑ Fairchild 1979, pp. 1; Johnston & Acton 2003, p. 177.
- ↑ Hayward et al. 2006, p. 437.
- ↑ Fairchild 1979, pp. 144–145.
- ↑ Fairchild 1979, p. 1.
- ↑ MacLeod et al. 1977;Fairchild 1979, figure 44c. This alignment through Discovery Bay is what Brandon (1989b, figure 1) calls the "Cenozoic truncation scar".
- ↑ Hayward et al. 2006, figure 2.
- ↑ Babcock, Suczek & Engebretson 1994, figure 1 and caption.
- ↑ Finn 1990, fig. 2.
- ↑ Particularly, prehnite coexisting with lawsonite or aragonite. Brandon 1989a, p. 1540.
- ↑ Brandon 1989a, p. 1520; Brandon 1989c, p. 1133.
- ↑ Brandon 1989a, p. 1541; Cowan 2003.
- ↑ Skehan 1966; Wells et al. 2010.
- ↑ If connected strike-slip faults having opposite senses of movement seems strange, consider the Crescent terrane (the part of Siletzia relevant here) as a very blunt arrowhead: the point is now near Darrington (unlabelled black square on map); the Devils Mountain and Darrington faults are the opposite sides of the arrow head. Arrayed with them in an arc are the various mélanges (metamorphosed subduction zone sediments) originally aligned along the OWL.
- ↑ Fairchild 1979, p. 140.
- ↑ Johnson et al. 2001, p. 43.
- ↑ Yorath, Kung & Franklin 2001.
References
- Babcock, R. S.; Suczek, C. A.; Engebretson, D. C. (1994), "The Crescent "Terrane", Olympic Peninsula and Southern Vancouver Island", in Lasmanis, Raymond; Cheney, Eric S., Regional Geology of Washington State (PDF), DGER Bulletin 80, Washington State DGER, pp. 141–157.
- Brandon, M. T. (December 1989a), "Deformational styles in a sequence of olistostromal mélanges, Pacific Rim Complex, western Vancouver Island, Canada" (PDF), GSAB 101 (12): 1520–1542, doi:10.1130/0016-7606(1989)101<1520:DSIASO>2.3.
- Brandon, M. T. (1989b), "Geology of the San Juan—Cascades Nappes, Northwestern Cascade Range and San Juan Islands", in Joseph, N. L.; et al., Geological guidebook for Washington and adjacent areas, DGER Information Circular 86 (PDF), Washington DGER, pp. 137–162.
- Brandon, M. T. (December 1989c), "Origin of igneous rocks associated with Mélanges of the Pacific Rim Complex, western Vancouver Island, Canada" (PDF), Tectonics 8 (6): 1115–1136, Bibcode:1989Tecto...8.1115B, doi:10.1029/TC008i006p01115.
- Clowes, R. M.; Brandon, M. T.; Green, A. G.; Yorath, C. J.; Sutherland Brown, A.; Kanasewich, E. R.; Spencer, C. (January 1987), "LITHOPROBE— southern Vancouver Island: Cenozoic subduction complex imaged by deep seismic reflections" (PDF), Canadian Journal of Earth Sciences 24 (1): 31–51, Bibcode:1987CaJES..24...31C, doi:10.1139/e87-004.
- Cowan, D. S. (25 August 2003), "Revisiting the Baranof-Leech River hypothesis for early Tertiary coastwise transport of the Chugach-Prince William Terrane", Earth and Planetary Science Letters 213 (3-4): 463–475, Bibcode:2003E&PSL.213..463C, doi:10.1016/S0012-821X(03)00300-5.
- Fairchild, L. H. (1979), The Leech River Unit and Leech River Fault, Southern Vancouver Island, British Columbia [masters thesis], Univ. of Washington.
- Finn, C. (November 10, 1990), "Geophysical constraints on Washington convergent margin structure", Journal of Geophysical Research 95 (B12): 19,553–19,546, Bibcode:1990JGR....9519533F, doi:10.1029/JB095iB12p19533.
- Groome, W. G.; Thorkelson, D. J.; Friedman, R. M.; Mortensen, J. K.; Massey, N. W. D.; Marshall, D. D.; Layer, P. W. (2003), "Magmatic and tectonic history of the Leech River Complex, Vancouver Island, British Columbia: Evidence for ridge-trench intersection and accretion of the Crescent Terrane" (PDF), Geological Society of America, Special Paper 371: 327–353, doi:10.1130/0-8137-2371-x.327.
- Hayward, N.; Nedimović, M. R.; Cleary, M.; Calvert, A. J. (2006), "Structural variation along the Devil’s Mountain fault zone, northwestern Washington" (PDF), Canadian Journal of Earth Sciences 43 (4): 433–466, Bibcode:2006CaJES..43..433H, doi:10.1139/E06-002.
- Johnson, S.Y.; Dadisman, S.V.; Mosher, D.C.; Blakely, R.J.; Childs, J.R. (2001), "Active tectonics of the Devils Mountain fault and related structures, northern Puget Lowland and eastern Strait of Juan de Fuca region, Pacific Northwest", U.S. Geological Society, Professional Paper 1642.
- Johnston, S. T.; Acton, S. (24 April 2003), "The Eocene Southern Vancouver Island Orocline — a response to seamount accretion and the cause of fold-and-thrust belt and extensional basin formation" (PDF), Tectonophysics 365 (104): 165–183, Bibcode:2003Tectp.365..165J, doi:10.1016/S0040-1951(03)00021-0.
- Skehan, J. W. (December 1966), "Continental-oceanic boundaries of earth and their relevance to tectonics speculations aobut the moon and the planets", Annals of the New York Academy of Sciences 140 (1): 107–113, doi:10.1111/j.1749-6632.1966.tb50950.x.
- Wells, R. E.; Bukry, D.; Wooden, J. L.; Friedman, R. M.; Haeussler, P. J. (Fall 2010), Magmatic and kinematic history of Siletzia, a Paleocene-Eocene accreted oceanic terrane in the Oregon Coast Range [abstract T12C-06].
- Yorath, C.; Kung, R.; Franklin, R. (2001), "Geoscape Victoria [poster]" (PDF), Geological Survey of Canada (Natural Resources Canada / Ressources naturelles Canada), Miscellaneous Report 74, 1 sheet, doi:10.4095/212597.