气候变化领域集成服务门户(CCPortal): Plate boundary localization, slip-rates and rupture segmentation of the Queen Charlotte Fault based on submarine tectonic geomorphology

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DOI	10.1016/j.epsl.2019.115882
	Plate boundary localization, slip-rates and rupture segmentation of the Queen Charlotte Fault based on submarine tectonic geomorphology
	Brothers D.S.; Miller N.C.; Barrie J.V.; Haeussler P.J.; Greene H.G.; Andrews B.D.; Zielke O.; Watt J.; Dartnell P.
发表日期	2020
ISSN	0012821X
卷号	530
英文摘要	Linking fault behavior over many earthquake cycles to individual earthquake behavior is a primary goal in tectonic geomorphology, particularly across an entire plate boundary. Here, we examine the 1150-km-long, right-lateral Queen Charlotte-Fairweather fault system using comprehensive multibeam bathymetry data acquired along the Queen Charlotte Fault (QCF) offshore southeastern Alaska and western British Columbia. Fine-scale analysis of tectonic geomorphology allowed us to identify and reconstruct 184 strike-slip piercing points over a 630 km stretch of the QCF. Age constraints from glacial recession and offshore sedimentation patterns yield a consistent slip-rate of ∼50–57 mm/yr since ∼17–12 ka, the fastest rate for a continent-ocean strike-slip fault on Earth. These slip-rates equal or exceed estimates of Pacific-North America (PA-NA) relative motion from global plate reconstructions, indicating that PA-NA motion is highly localized. The QCF cuts the seafloor along a narrow and unusually straight trace for its entire length and multiple fault traces are observed only at local step-overs. The geometry and behavior of the QCF over many earthquake cycles is simple and typical of mature faults with relatively homogeneous stress fields. Since the QCF is the primary PA-NA plate boundary, we used the trace of the QCF to define the small circle path for relative plate motion and computed the associated Euler pole. Predicted along-strike obliquity variations based on the new pole agree with observed tectonic geomorphology and suggest that previous global plate reconstructions overestimated the degree of oblique convergence along the QCF. We also find that subtle, long-wavelength (75–150 km) bends and discrete step-overs appear to define the endpoints of M>7 earthquakes, suggesting that obliquity and resultant fault geometry may control rupture segmentation and asperity development. Lastly, the agreement between predicted obliquity and tectonic geomorphology along the entire length of QCF compelled a reevaluation of regional tectonic models. In the north, the eastern Yakatat Terrane appears to be translating northwest with the Pacific plate, and slip transferred from the QCF to the Fairweather Fault results in ∼20 mm/yr of convergence along the southern St. Elias mountains. In the south, we predict a reduced rate of convergence along the QCF west of Haida Gwaii (∼5–6 mm/yr of shortening, on average) relative to previous studies. Our results support a model for transpression and strike-slip partitioning along the edge of a hot and weak Pacific Plate, leading to crustal thickening and growth of the Queen Charlotte Terrace to the west of Haida Gwaii. © 2019
关键词	asperity continental slope glacial outwash multibeam bathymetry Pacific-North America plate boundary strain partitioning transform fault
英文关键词	Bathymetry; Earthquakes; Geomorphology; Glacial geology; Landforms; Offshore oil well production; Poles; Repair; Strike-slip faults; Structural geology; Transform faults; asperity; Continental slope; glacial outwash; Multibeam bathymetry; Plate boundaries; Strain partitioning; Fault slips; bathymetric survey; continental slope; outwash; Pacific plate; plate boundary; plate motion; plate tectonics; rupture; segmentation; slip rate; strike-slip fault; tectonic evolution; tectonic setting; Alaska; British Columbia; Canada; Queen Charlotte Islands; United States
语种	英语
来源期刊	Earth and Planetary Science Letters
文献类型	期刊论文
条目标识符	http://gcip.llas.ac.cn/handle/2XKMVOVA/202510
作者单位	Pacific Coastal and Marine Science Center, U.S. Geological Survey, Mission Street, Santa Cruz, CA 95060, United States; Woods Hole Coastal and Marine Science Center, U.S. Geological Survey, Woods Hole Road, Woods Hole, MA 02543, United States; Geological Survey of Canada (Pacific), West Saanich Rd, Sidney, BC V8L 4B2, Canada; Alaska Science Center, U.S. Geological Survey, University Dr., Anchorage, AK 99508, United States; Moss Landing Marine Laboratories, Tombolo Mapping Laboratory, San Jose State University, Anchor Rock Lane, Eastsound, WA 98245, United States; Division of Physical Sciences and Engineering, King Abdullah University of Science and Technology (KAUST), Thuwal, Saudi Arabia
推荐引用方式 GB/T 7714	Brothers D.S.,Miller N.C.,Barrie J.V.,et al. Plate boundary localization, slip-rates and rupture segmentation of the Queen Charlotte Fault based on submarine tectonic geomorphology[J],2020,530.
APA	Brothers D.S..,Miller N.C..,Barrie J.V..,Haeussler P.J..,Greene H.G..,...&Dartnell P..(2020).Plate boundary localization, slip-rates and rupture segmentation of the Queen Charlotte Fault based on submarine tectonic geomorphology.Earth and Planetary Science Letters,530.
MLA	Brothers D.S.,et al."Plate boundary localization, slip-rates and rupture segmentation of the Queen Charlotte Fault based on submarine tectonic geomorphology".Earth and Planetary Science Letters 530(2020).