Stratigraphic record of basin development within the San Andreas fault system: Late Cenozoic Fish Creek-Vallecito basin, southern California

Dorsey, Rebecca J.; Housen, Bernard A.; Jänecke, Susanne U.; Fanning, Christopher; Spears, A. L.

doi:10.1130/b30168.1

Cited by 95 publications

(206 citation statements)

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“…The lower megabreccia is overlain by the Fish Creek Gypsum and locally-sourced turbidites of the Latrania Formation (Lycium Member), which record marine incursion into the Salton Trough region ~6.3Ma ( Fig. 15A; Dorsey et al, 2007Dorsey et al, , 2011. Lycium Member turbidites are overlain by a second megabreccia that was emplaced catastrophically into a marine basin (Kerr and Abbott, 1996;Abbott et al, 2002) immediately prior to the end of the Miocene epoch (Fig.…”

Section: Stratigraphic Summarymentioning

confidence: 99%

“…15, 16). Thick-bedded sandstones of the Wind Caves member record deposition by sand-rich turbidity currents in a submarine canyon that was fed by early Pliocene input from the Colorado River Dorsey et al, 2007Dorsey et al, , 2011Kimbrough et al, 2015;Cloos, 2014). Colorado River-derived turbidites of the Wind Caves member are restricted to an ~10-km wide paleocanyon, and pinch out over b10-15 km in the down-transport direction to the Coyote Mountains where the Wind Caves member is absent and the Coyote Clay rests directly on older deposits Bykerk-Kauffman, 2017) Shirvell, 2006).…”

Section: Stratigraphic Synthesis Western Salton Troughmentioning

confidence: 99%

“…This age assignment is consistent with independently determined correlation of magnetic reversals to the geomagnetic polarity timescale (Dorsey et al, 2007. Amphistegina gibbosa became extinct in the northern Gulf and Salton Trough region at approximately 5.3 Ma (Ingle, 1974;McDougall et al, 1999;Dorsey et al, 2007Dorsey et al, , 2011. The first occurrence of T. anfracta is 5.8 Ma, the range of S. globigerus in the equatorial Pacific is 5.45 to 3.6 Ma, and the range of G. multiloba is Miocene to Pliocene (Blow, 1979;Resig, 1989Resig, , 1993Miranda-Martínez et al, 2017;A.Y.Miranda-Martínez, personal communication, 2017).…”

Section: Micropaleontology and Biostratigraphymentioning

confidence: 99%

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Punctuated Sediment Discharge During Early Pliocene Birth of the Colorado River: Evidence from Regional Stratigraphy, Sedimentology, and Paleontology

Dorsey¹,

O’Connell²,

McDougall-Reid³

et al. 2017

Preprint

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The Colorado River in the southwestern U.S. provides an excellent natural laboratory for studying the origins of a continent-scale river system, because deposits that formed prior to and during river initiation are well exposed in the lower river valley and nearby basinal sink. This paper presents a synthesis of regional stratigraphy, sedimentology, and micropaleontology from the southern Bouse Formation and similar-age deposits in the western Salton Trough, which we use to interpret processes that controlled the birth and early evolution of the Colorado River. The southern Bouse Formation is divided into three laterally persistent members: basal carbonate, siliciclastic, and upper bioclastic members. Basal carbonate accumulated in a tidedominated marine embayment during a rise of relative sea level between ~6.3 and 5.4 Ma, prior to arrival of the Colorado River. The transition to green claystone records initial rapid influx of river water and its distal clay wash load into the subtidal marine embayment at ~5.4-5.3 Ma. This was followed by rapid southward progradation of the Colorado River delta, establishment of the earliest through-flowing river, and deposition of river-derived turbidites in the western Salton Trough (Wind Caves paleocanyon) between ~5.3 and 5.1 Ma. Early delta progradation was followed by regional shut-down of river sand output between ~5.1 and 4.8 Ma that resulted in deposition of marine clay in the Salton Trough, retreat of the delta, and re-flooding of the lower river valley by shallow marine water that deposited the Bouse upper bioclastic member. Resumption of sediment discharge at ~4.8 Ma drove massive progradation of fluvial-deltaic deposits back down the river valley into the northern Gulf and Salton Trough.These results provide evidence for a discontinuous, start-stop-start history of sand output during initiation of the Colorado River that is not predicted by existing models for this system. The underlying controls on punctuated sediment discharge are assessed by comparing the depositional chronology to the record of global sea-level change. The lower Colorado River Valley and Salton Trough experienced marine transgression during a gradual fall in global sea level between ~6.3 and 5.5 Ma, implicating tectonic subsidence as the main driver of latest Miocene relative sea-level rise. A major fall of global sea level at 5.3Ma outpaced subsidence and drove regional delta progradation, earliest flushing of Colorado River sand into the northern Gulf of California, and erosion of Bouse basal carbonate and siliciclastic members. The lower Colorado River valley was re-flooded by shallow marine waters during smaller changes in global sea level ~ 5.1-4.8 Ma, after the river first ran through it, which requires a mechanism to stop delivery of sand to the lower river valley. We propose that tectonically controlled subsidence along the lower Colorado River, upstream of the southern Bouse study area, temporarily trapped sediment and stopped delivery of sand to the lower river valley and nort...

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Section: Stratigraphic Summarymentioning

confidence: 99%

Section: Stratigraphic Synthesis Western Salton Troughmentioning

confidence: 99%

Section: Micropaleontology and Biostratigraphymentioning

confidence: 99%

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Punctuated Sediment Discharge During Early Pliocene Birth of the Colorado River: Evidence from Regional Stratigraphy, Sedimentology, and Paleontology

Dorsey¹,

O’Connell²,

McDougall-Reid³

et al. 2017

Preprint

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“…7 Ma, ~0.5-1.0 m.y. before the earliest marine incursions in the northern Gulf of California (e.g., McDougall, 2008;Dorsey et al, 2011;Bennett et al, 2012b).…”

Section: Early Marine Incursions and Basin Formationmentioning

confidence: 99%

“…7 Ma, ~0.5-1.0 m.y. before the earliest marine incursions in the northern Gulf of California (e.g., McDougall, 2008;Dorsey et al, 2011;Bennett et al, 2012b).The Late Miocene rocks of the Santa Rosalía Basin inform us of conditions during deposition of the associated EGE. This basin is fl oored by scattered marine limestone and gypsum units that unconformably overlie heavily faulted prerift Comondu arc volcanic rocks (Wilson and Rocha, 1955), indicating that these units represent the fi rst deposition in proto-gulf extensional basins.…”

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confidence: 99%

Evolution of oceanic margins : rifting in the Gulf of California and sediment diapirism and mantle hydration during subduction

Miller¹

2013

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This thesis investigates three processes that control the evolution of oceanic margins. Chapter 2 presents seismic images of a ~2-km-thick evaporite body in Guaymas Basin, central Gulf of California. In rifts, evaporites form under conditions unique to the latest stages of continental rupture, and the presence, age, thickness, and shape place new constraints on the history of early rifting there. Chapter 3 presents numerical experiments that show that diapirs can form in sediments on the down-going plate in subduction zones and rise into the mantle wedge, delivering the sedimentary component widely observed in arc magmas. Chapter 4 presents measurements of seismic anisotropy from wide-angle, active-source data from the Middle America Trench that address the hypothesis that the upper mantle is hydrated by seawater flowing along outer-rise normal faults. These measurements indicate that the upper mantle is ~1.57 to 6.89% anisotropic, and this anisotropy can be attributed to bendingrelated faulting and an inherited mantle fabric. Accounting for anisotropy reduces previous estimates for the amount of water stored in the upper mantle of the downgoing plate from ~2.5 to 1.5 wt%, a significant change in subduction zone water budgets. AcknowledgementsThis thesis punctuates my own transformation from student to new scientist, but it also marks a change from many other states of incipiency to nascence. In any transformation and in any new thing there is woe. This woe can be wisdom, but it can also be madness. Dan Lizarralde has a knack for sorting wisdom from madness, and he showed me how to see the difference and navigate the space in between. I am grateful that he took a chance on me, first as a summer student at WHOI and then as a graduate student, and he never stopped holding the proverbial carrot at just the right distance.Mark Behn and John Collins also understand wisdom and madness. They took an early interest in my work and have offered ceaseless encouragement since I first arrived at WHOI. They also provided the critical eyes that are essential to good science, and to the development of good scientists, and I am truly grateful for time I shared with these guys. Donna Shillington and Alison Malcolm had no hesitations about joining my thesis committee, and they have been nothing but supportive the whole time.I am lucky to have spent 5 months at sea with the fine officers and crews of the R/V Langseth, R/V Endeavor, and F/V Tiki. At WHOI, talented people like Jeff Dusenberry and Jonathan Murry kept our computers and code running. I am grateful that the folks in the education offices MIT and WHOI work hard to make the Joint Program the amazing experience it is. I am also thankful that the U.S. values scientists and students and supports us by giving grants like National Science Foundation (NSF) Division of Ocean Science (OCE) #824497 and NSF OCE-MARGINS #825178 and #841063 to Dan Lizarralde, as well as NSF Division of Earth Sciences #0652707 to Mark Behn.Camilo Ponton can talk science, but he was also there ...

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Deviations from self-similarity in barchan form and flux: The case of the Salton Sea dunes, California

Pelletier

2013

J. Geophys. Res. Earth Surf.

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[1] Barchans are the type of aeolian dune associated with a relatively uniform wind direction, incomplete sand coverage of the substrate, and low vegetation cover. Here I present an analysis of the morphology and migration rates of 40 dunes in the Salton Sea dune field using historical aerial orthophotographs, airborne laser swath mapping, terrestrial laser scanning, and measurements of the aerodynamic roughness length derived from wind velocity profiles. The data demonstrate that the Salton Sea dunes deviate from self-similarity such that smaller dunes have a lower ratio of slip face height to crest height and a lower slope, on average, compared with larger dunes and that smaller dunes migrate more slowly than would be predicted based on an inverse relationship between migration rate and dune height. The lack of self-similarity in barchans has been attributed to the dependence of speed-up ratios on dune size and the presence of a finite saturation length in the physics of aeolian transport. Here I argue that deviations from self-similarity at this study site are more likely due to the systematic decrease in aerodynamic roughness length with increasing elevation on stoss slopes. The data set I developed should prove useful to the aeolian geomorphic community for the further testing of models for barchan evolution.

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Stratigraphic record of basin development within the San Andreas fault system: Late Cenozoic Fish Creek-Vallecito basin, southern California

Cited by 95 publications

References 80 publications

Punctuated Sediment Discharge During Early Pliocene Birth of the Colorado River: Evidence from Regional Stratigraphy, Sedimentology, and Paleontology

Punctuated Sediment Discharge During Early Pliocene Birth of the Colorado River: Evidence from Regional Stratigraphy, Sedimentology, and Paleontology

Evolution of oceanic margins : rifting in the Gulf of California and sediment diapirism and mantle hydration during subduction

Deviations from self-similarity in barchan form and flux: The case of the Salton Sea dunes, California

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