From Continental Shelf to Slope: Mapping the Oceanic Realm
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This volume covers multi-disciplinary Research and Development contributions from Europe, Asia and North America on geology, geophysics, bathymetric and biological aspects, towards data sampling, acquisition, data analysis and its results, and innovative ways of data access. It also presents the development of processes to map, harmonize and integrate marine data across EEZ boundaries, an impressive example of which is the European EMODnet (European Marine Observation and Data network) initiative. EMODnet assembles scattered and partially hidden marine data into continentally harmonized geospatial data products for public benefit and increasingly within overseas collaboration. The volume also aims to shed light on an evaluation of biological and mineral resources and environmental assessments at continental shelf to slope depths. Western Pacific examples provide excellent case studies for this topic. Mapping of the Ocean Realm is not only for scientific purposes, but also for the people who live by the seas. Communication amongst scientists and multiple stakeholders is essential for living sustainably with the seas. In this volume we encourage dialogue amongst all the stakeholders.
Faulting within the San Juan–southern Gulf Islands Archipelagos, upper plate deformation of the Cascadia subduction complex
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Published:September 07, 2022
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CiteCitation
H. Gary Greene, J. Vaughn Barrie, 2022. "Faulting within the San Juan–southern Gulf Islands Archipelagos, upper plate deformation of the Cascadia subduction complex", From Continental Shelf to Slope: Mapping the Oceanic Realm, K. Asch, H. Kitazato, H. Vallius
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Abstract
The San Juan–southern Gulf Islands Archipelago of Washington State, USA and western Canada is located on the upper plate of the Cascadia subduction zone, in the forearc between the trench and volcanic arc. Onland and island investigations show many faults within the region that primarily represent old, inactive faults associated with transport, subduction and accretion of tectonostratigraphic terranes. However, until recently little geologic investigation and mapping have been done in the offshore. From these narrow straits, channels and sounds we have collected and interpreted high-resolution multibeam echosounder bathymetric data, 3.5 kHz sub-bottom and Huntec seismic-reflection profiles, and piston-cores to identify and date recently active faults. Previous studies by us focused on the earlier recognized active Devils Mountain fault zone that bounds the southern part of the Archipelago and the recently reported newly mapped active Skipjack Island fault zone that bounds the northern part. These transcurrent fault zones appear to be deforming and rotating the Archipelago. We concentrate on the unique deformation occurring within the seaways to determine the relationship and styles of faulting associated with these active bounding fault zones and relate the fault geometry and kinematics to one other subduction complex, the New Hebrides island arc of Vanuatu.
- accretion
- active faults
- bathymetry
- British Columbia
- Canada
- Cascadia subduction zone
- channels
- cores
- deformation
- duplexes
- echo sounding
- fault zones
- faults
- geometry
- geophysical methods
- geophysical profiles
- geophysical surveys
- glaciation
- kinematics
- laser methods
- lidar methods
- mapping
- Melanesia
- multibeam methods
- Oceania
- plate tectonics
- plates
- reflection methods
- rotation
- San Juan County Washington
- San Juan Islands
- seismic methods
- seismic profiles
- subduction
- surveys
- tectonics
- tectonostratigraphic units
- terranes
- transcurrent faults
- transport
- United States
- Vancouver Island
- Vanuatu
- Washington
- Western Canada
- Lummi Island
- Lopez Island
- Devils Mountain fault zone
- Haro Strait
- Skipjack Island fault zone
- Gulf Islands Archipelago
- Southern Georgia Strait