TY - JOUR
T1 - New kinematic models for Pacific-North America motion from 3 MA to present, II
T2 - Evidence for a "Baja California shear zone"
AU - Dixon, Timothy
AU - Farina, Fred
AU - DeMets, Charles
AU - Suarez-Vidal, Francisco
AU - Fletcher, John
AU - Marquez-Azua, Bertha
AU - Miller, Meghan
AU - Sanchez, Osvaldo
AU - Umhoefer, Paul
PY - 2000
Y1 - 2000
N2 - We use new models for present-day Pacific-North America motion to evaluate the tectonics of offshore regions west of the Californias. Vandenburg in coastal Alta California moves at the Pacific plate velocity within uncertainties (∼1 mm/yr) after correcting for strain accumulation on the San Andreas and San Gregorio-Hosgri faults with a model that includes a viscoelastic lower crust. Modeled and measured velocities at coastal sites in Baja California south of the Agua Blanca fault, a region that most previous models consider Pacific plate, differ by 3-8 mm/yr, with coastal sites moving slower that the Pacific plate. We interpret these discrepancies in terms of strain accumulation on known on-shore faults, combined with right lateral slip at a rate of 3-4 mm/yr on additional faults offshore peninsular Baja California in the Pacific. Offshore seismicity, offset Quaternary features along the west coast of Baja California, and a discrepancy between the magnetically determined spreading rate in the Gulf Rise and the total plate rate from a geological model provide independent evidence for a "Baja California shear zone".
AB - We use new models for present-day Pacific-North America motion to evaluate the tectonics of offshore regions west of the Californias. Vandenburg in coastal Alta California moves at the Pacific plate velocity within uncertainties (∼1 mm/yr) after correcting for strain accumulation on the San Andreas and San Gregorio-Hosgri faults with a model that includes a viscoelastic lower crust. Modeled and measured velocities at coastal sites in Baja California south of the Agua Blanca fault, a region that most previous models consider Pacific plate, differ by 3-8 mm/yr, with coastal sites moving slower that the Pacific plate. We interpret these discrepancies in terms of strain accumulation on known on-shore faults, combined with right lateral slip at a rate of 3-4 mm/yr on additional faults offshore peninsular Baja California in the Pacific. Offshore seismicity, offset Quaternary features along the west coast of Baja California, and a discrepancy between the magnetically determined spreading rate in the Gulf Rise and the total plate rate from a geological model provide independent evidence for a "Baja California shear zone".
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U2 - 10.1029/2000GL008529
DO - 10.1029/2000GL008529
M3 - Article
AN - SCOPUS:0034480792
SN - 0094-8276
VL - 27
SP - 3961
EP - 3964
JO - Geophysical Research Letters
JF - Geophysical Research Letters
IS - 23
ER -