Microcontinent Breakup and Links to Possible Plate Boundary Reorganization in the Northern Gulf of California, México

Abstract The southern Baja California (Mexico) microplate has been rapidly moving away from the North America plate since ca. 12 Ma. This relative motion toward the northwest developed an oblique-divergent plate boundary that formed the Gulf of California. The rift-drift hypothesis postulates that when a continent ruptures and seafloor spreading commences, rifting on the plate margins ceases, and the margins start to drift, subside, and accumulate postrift sediments, eventually becoming a passive margin. In contrast to this hypothesis, the southern part of the Baja California microplate (BCM), and in particular its actively deforming eastern boundary zone, has continued significant rifting for millions of years after seafloor spreading initiated within the southern Gulf of California at 6–2.5 Ma. This is a process we call “rifting-while-drifting.” Global positioning system (GPS)–based data collected from 1998 to 2011 show relative motion across the eastern boundary zone up to ∼2–3.2 mm/yr with respect to a stable BCM. Furthermore, the velocity directions are compatible with normal faulting across the eastern boundary zone nearly perpendicular to the trend of the plate boundary at the latitude of La Paz and therefore a highly strain partitioned domain. North of 25°N latitude up to the Loreto area, there is a domain with no strain partitioning, and northwest-directed transtensional deformation dominates. From long-term geologic and paleoseismology studies, late Quaternary faulting rates are equal to or less than the GPS-derived rates, while geologic rates older than 1–2 Ma are commonly much higher. We suggest that the “rifting-while-drifting” process may be caused by the large topographic relief across the BCM margin, which created a significant gradient in gravitational potential energy that helps in driving continued relatively slow faulting. The relief was inherited from the much faster faulting of the BCM eastern boundary zone before plate motions largely localized along the modern transform–spreading centers in the axis of the Gulf of California. The low sediment flux from the small drainages and arid climate on the southern Baja California Peninsula result in the maintenance of underfilled to starved basins, and the relatively slow late Quaternary active faulting promotes continued topographic relief over millions of years.

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Oblique rifting: the rule, not the exception

10.5194/se-2018-63 ◽

2018 ◽

Author(s):

Sascha Brune ◽

Simon E. Willliams ◽

R. Dietmar Müller

Keyword(s):

Gulf Of California ◽

Plate Boundary ◽

Strain Analysis ◽

Dominant Mode ◽

Plate Boundaries ◽

Tectonic Plates ◽

Relative Extension ◽

Reconstruction Software ◽

Oblique Rifting ◽

Extension Direction

Abstract. Movements of tectonic plates often induce oblique deformation at divergent plate boundaries. This is in striking contrast with traditional conceptual models of rifting and rifted margin formation, which often assume 2D deformation where the rift velocity is oriented perpendicular to the plate boundary. Here we quantify the validity of this assumption by analysing the kinematics of major continent-scale rift systems in a global plate tectonic reconstruction from the onset of Pangea breakup until present-day. We evaluate rift obliquity by joint examination of relative extension velocity and local rift trend using the script-based plate reconstruction software pyGPlates. Our results show that the global mean rift obliquity amounts to 34° with a standard deviation of 24°, using the convention that the angle of obliquity is spanned by extension direction and rift trend normal. We find that more than ~ 70 % of all rift segments exceeded an obliquity of 20° demonstrating that oblique rifting should be considered the rule, not the exception. In many cases, rift obliquity and extension velocity increase during rift evolution (e.g. Australia-Antarctica, Gulf of California, South Atlantic, India-Antarctica), which suggests an underlying geodynamic correlation via obliquity-dependent rift strength. Oblique rifting produces 3D stress and strain fields that cannot be accounted for in simplified 2D plane strain analysis. We therefore highlight the importance of 3D approaches in modelling, surveying, and interpretation of most rift segments on Earth where oblique rifting is the dominant mode of deformation.

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Immature plate boundary zones studied with a submersible in the Gulf of California

Geological Society of America Bulletin ◽

10.1130/0016-7606(1980)91<555:ipbzsw>2.0.co;2 ◽

1980 ◽

Vol 91 (9) ◽

pp. 555 ◽

Cited By ~ 36

Author(s):

PETER LONSDALE ◽

L. A. LAWVER

Keyword(s):

Gulf Of California ◽

Plate Boundary

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Relation of the Puertecitos volcanic province, Baja California, Mexico, to development of the plate boundary in the Gulf of California

Cenozoic tectonics and volcanism of Mexico ◽

10.1130/0-8137-2334-5.143 ◽

2000 ◽

Cited By ~ 14

Author(s):

Joann M. Stock

Keyword(s):

Gulf Of California ◽

Baja California ◽

Plate Boundary ◽

Volcanic Province

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The source mechanism of the August 7, 1966 El Golfo earthquake

Bulletin of the Seismological Society of America ◽

10.1785/bssa0680051281 ◽

1978 ◽

Vol 68 (5) ◽

pp. 1281-1292

Author(s):

John E. Ebel ◽

L. J. Burdick ◽

Gordon S. Stewart

Keyword(s):

Surface Wave ◽

Stress Drop ◽

Gulf Of California ◽

Body Wave ◽

Source Parameters ◽

High Stress ◽

Plate Boundary ◽

The Body ◽

Body Waves ◽

Wave Radiation

abstract The El Golfo earthquake of August 7, 1966 (mb = 6.3, MS = 6.3) occurred near the mouth of the Colorado River at the northern end of the Gulf of California. Synthetic seismograms for this event were computed for both the body waves and the surface waves to determine the source parameters of the earthquake. The body-wave model indicated the source was a right lateral, strike-slip source with a depth of 10 km and a far-field time function 4 sec in duration. The body-wave moment was computed to be 5.0 × 1025 dyne-cm. The surface-wave radiation pattern was found to be consistent with that of the body waves with a surface-wave moment of 6.5 × 1025 dyne-cm. The agreement of the two different moments indicates that the earthquake had a simple source about 4 sec long. A comparison of this earthquake source with the Borrego Mountain and Truckee events demonstrates that all three of these earthquakes behaved as high stress-drop events. El Golfo was shown to be different from the low stress-drop, plate-boundary events which were located on the Gibbs fracture zone in 1967 and 1974.

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Oblique rifting: the rule, not the exception

Solid Earth ◽

10.5194/se-9-1187-2018 ◽

2018 ◽

Vol 9 (5) ◽

pp. 1187-1206 ◽

Cited By ~ 19

Author(s):

Sascha Brune ◽

Simon E. Williams ◽

R. Dietmar Müller

Keyword(s):

Gulf Of California ◽

Plate Boundary ◽

Strain Analysis ◽

Dominant Mode ◽

Plate Boundaries ◽

Tectonic Plates ◽

Relative Extension ◽

Reconstruction Software ◽

Oblique Rifting ◽

Extension Direction

Abstract. Movements of tectonic plates often induce oblique deformation at divergent plate boundaries. This is in striking contrast with traditional conceptual models of rifting and rifted margin formation, which often assume 2-D deformation where the rift velocity is oriented perpendicular to the plate boundary. Here we quantify the validity of this assumption by analysing the kinematics of major continent-scale rift systems in a global plate tectonic reconstruction from the onset of Pangea breakup until the present day. We evaluate rift obliquity by joint examination of relative extension velocity and local rift trend using the script-based plate reconstruction software pyGPlates. Our results show that the global mean rift obliquity since 230 Ma amounts to 34° with a standard deviation of 24°, using the convention that the angle of obliquity is spanned by extension direction and rift trend normal. We find that more than ∼ 70 % of all rift segments exceeded an obliquity of 20° demonstrating that oblique rifting should be considered the rule, not the exception. In many cases, rift obliquity and extension velocity increase during rift evolution (e.g. Australia-Antarctica, Gulf of California, South Atlantic, India-Antarctica), which suggests an underlying geodynamic correlation via obliquity-dependent rift strength. Oblique rifting produces 3-D stress and strain fields that cannot be accounted for in simplified 2-D plane strain analysis. We therefore highlight the importance of 3-D approaches in modelling, surveying, and interpretation of most rift segments on Earth where oblique rifting is the dominant mode of deformation.

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