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Structure, origin, and deformation of the lithosphere in the northern Canadian Cordillera from high-resolution, passive-source seismic velocity models
  • +3
  • Clément Estève,
  • P Audet,
  • D L Schutt,
  • R C Aster,
  • A J Schaeffer,
  • J F Cubley
Clément Estève
Department of Meteorology and Geophysics, University of Vienna

Corresponding Author:[email protected]

Author Profile
P Audet
Department of Earth and Environmental Sciences, University of Ottawa
D L Schutt
Department of Geosciences and Warner College of Natural Resources, Colorado State University
R C Aster
Department of Geosciences and Warner College of Natural Resources, Colorado State University
A J Schaeffer
Centre for Northern Innovation in Mining, Yukon University
J F Cubley
Centre for Northern Innovation in Mining, Yukon University

Abstract

The recent deployment of temporary broadband seismic networks, notably the EarthScope USArray-Transportable Array (TA), has drastically improved the station coverage across northwestern Canada over the last ten years, enabling application of high-resolution passive-source seismic methods (i.e., seismic tomography, receiver functions and core phase shear wave splitting). This review highlights the main discoveries pertaining to the seismic velocity structure, origin and deformation of the lithosphere in the northern Canadian Cordillera (NCC). High-resolution seismic tomography models reveal that the lower crust in the NCC is marked by low velocity anomalies extending from the Gulf of Alaska to the Cordilleran deformation front, which are interpreted to reflect elevated temperatures that buoyantly support regional high elevations and potentially represent the seismic signature of strain transfer from the Yakutat collision zone to the Mackenzie Mountains. The Moho is relatively flat and shallow across the NCC, and is underlain by a thin layer of mantle lithosphere. Seismic velocity models further unveiled large-scale mantle structures associated with the unexposed Mackenzie craton in the north, and the Liard Transfer Zone in the south, which appear to buttress the NCC and further focus deformation in the eastern NCC. Seismic anisotropy and tomography provide evidence that the Tintina and Denali faults penetrate into the lithospheric mantle and played a first order role in shaping the present-day NCC. We propose that future studies should aim to: 1) resolve the shape of the Cordillera-craton boundary at upper mantle depths; 2) accurately estimate the lithosphere thickness in the NCC; and 3) improve coverage in the Beaufort Sea to understand the controls on convergent tectonics in the northern NCC.
01 Aug 2023Submitted to ESS Open Archive
04 Aug 2023Published in ESS Open Archive