Regional Geology of Mount Diablo, California: Its Tectonic Evolution on the North America Plate Boundary
Mount Diablo and the geology of the Central California Coast Ranges are the subject of a volume celebrating the Northern California Geological Society’s 75th anniversary. The breadth of research illustrates the complex Mesozoic to Cenozoic tectonic evolution of the plate boundary. Recent faulting and folding along the eastern edge of the San Andreas system have exposed in the mountain a core of Franciscan accretionary wedge complex faulted against Cretaceous and Cenozoic forearc strata. The Memoir includes papers on structure, stratigraphy, tephrochronology, zircon provenance studies, apatite fission track analyses, and foraminifera and calcareous plankton assemblages tied to Cenozoic climate events. Chapters also address the history of geologic work in the area and the resource development of oil and gas, mercury, coal, and sand, and road aggregate.
Late Cenozoic tephrochronology of the Mount Diablo area within the evolving plate-tectonic boundary zone of northern California
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Published:September 27, 2021
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CiteCitation
Andrei M. Sarna-Wojcicki, Raymond Sullivan, Alan Deino, Laura C. Walkup, J. Ross Wagner, Elmira Wan, 2021. "Late Cenozoic tephrochronology of the Mount Diablo area within the evolving plate-tectonic boundary zone of northern California", Regional Geology of Mount Diablo, California: Its Tectonic Evolution on the North America Plate Boundary, Raymond Sullivan, Doris Sloan, Jeffrey R. Unruh, David P. Schwartz
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ABSTRACT
We present a tephrochronologic/chronostratigraphic database for the Mount Diablo area and greater San Francisco Bay region that provides a spatial and temporal framework for geologic studies in the region, including stratigraphy, paleogeography, tectonics, quantification of earth surface processes, recurrence of natural hazards, and climate change. We identified and correlated 34 tephra layers within this region using the chemical composition of their volcanic glasses, stratigraphic sequence, and isotopic and other dating techniques. Tephra layers range in age from ca. 65 ka to ca. 29 Ma, as determined by direct radiometric techniques or by correlation to sites where they have been dated. The tephra layers are of Quaternary or Neogene age except for two that are of Oligocene age. We correlated the tephra layers among numerous sites throughout northern California. Source areas of the tephra layers are the Snake River–Yellowstone hotspot trend of northern Nevada, southern Idaho, and western Wyoming; the Nevadaplano caldera complex of central Nevada; the Jemez Mountains–Valles Caldera in northwestern New Mexico; the Southern Nevada volcanic field and related source areas in eastern California and west-central Nevada; the Quien Sabe–Sonoma volcanic centers of the California Coast Ranges; and the young Cascade Range volcanic centers of northeastern California and Oregon.
- California
- Cascade Range
- Cenozoic
- chemical composition
- chronostratigraphy
- Coast Ranges
- Contra Costa County California
- correlation
- electron microscopy data
- eruptions
- Esmeralda County Nevada
- Glass Mountains
- glasses
- Idaho
- igneous rocks
- Jemez Mountains
- Mono County California
- Mono Craters
- Neogene
- Nevada
- New Mexico
- Northern California
- plate boundaries
- plate tectonics
- pyroclastics
- Quaternary
- San Francisco Bay region
- SEM data
- sequence stratigraphy
- Sierra Nevada
- Silver Peak Mountains
- Snake River plain
- succession
- tephrochronology
- Tertiary
- tuff
- United States
- upper Cenozoic
- Valles Caldera
- volcanic fields
- volcanic glass
- volcanic rocks
- Washington
- Yellowstone Hot Spot
- Mount Diablo
- Briones Formation
- Cierbo Formation
- Kirker Tuff
- Southern Nevada volcanic field