Your search keyword '"Field, M. E."' showing total 5 results

1. A Comprehensive Assessment of Submarine Landslides and Mass Wasting Processes Offshore Southern California.

Author

Walton, Maureen A. L., Conrad, James E., Papesh, Antoinette G., Brothers, Daniel S., Kluesner, Jared W., McGann, Mary, and Dartnell, Peter

Subjects

LANDSLIDES, MARINE sediments, GEOPHYSICAL surveys, COASTAL sediments, EARTHQUAKES, SEDIMENTATION & deposition, MARINE debris

Abstract

It is critical to characterize submarine landslide hazards near dense coastal populations, especially in areas with active faults, which can trigger slope failure, subsequent tsunamis, and damage seabed infrastructure during earthquake shaking. Offshore southern California, numerous marine geophysical surveys have been conducted over the past decade, and high‐resolution bathymetric and subsurface data now cover about 60 percent of the total region between Point Conception and the United States‐Mexico border from the California coast out to the base of Patton Escarpment ∼200 km offshore. In a comprehensive compilation and interpretive mapping effort, we find evidence of seafloor failure throughout offshore southern California with nearly 1,500 submarine landslide‐related features, including 63 discrete slide deposits with debris and >1,400 slide‐related scarps. In our analysis, we highlight new mapping of submarine landslides in Catalina Basin, the Del Mar slide, the San Gabriel slide complex, and the 232 km2 San Nicolas slide, the largest area of any known submarine landslide mass offshore southern California. Analysis of the spatial distribution of submarine landslide features suggests that most mapped slide features are located relatively near coastal sediment sources, particularly during sea‐level lowstand conditions, which underscores the importance of sediment supply and sediment accumulation on low‐gradient slopes as failure preconditioning processes. Tectonically driven uplift at shelf edges and along basin flanks is another key preconditioning factor, and our results also suggest that earthquakes along active faults trigger mass wasting, especially for repeated, small‐scale failures on tectonically steepened slopes. Plain Language Summary: Submarine landslides can damage seabed infrastructure such as cables and moorings, cause tsunamis, and be triggered by shaking from earthquakes. It is important to understand the risk of submarine landslides near dense coastal populations, particularly where earthquakes also pose hazards. Offshore southern California, we have new high‐resolution seafloor and subsurface imaging data that help us to identify submarine landslide deposits in the marine environment. In our study, we map and compile evidence for submarine landslides and find nearly 1,500 slide‐related features, 63 of which feature significant debris deposits. We describe some of the larger slides in this study for the first time, including submarine landslides in Catalina Basin, the Del Mar slide, the San Gabriel slide complex, and the 232 square kilometer San Nicolas slide, which is one of the largest known submarine landslide masses offshore southern California. Our work suggests that submarine landslide failure processes offshore southern California require a combination of (a) significant sediment supply, which is enhanced during low sea‐level conditions, (b) uplift and steepening along faults, and (c) earthquake shaking to trigger slide events. Key Points: Comprehensive analysis of submarine landslides in southern California provides new metrics on their size, distribution, timing, and geologySubmarine landslide failure processes are controlled by a combination of sediment deposition, tectonic uplift, and earthquake triggeringSmall‐scale failures dominate steep areas near Quaternary faults; large slides tend to occur on lower slopes farther from faults [ABSTRACT FROM AUTHOR]

Published

2024

2. A Large Sediment Accretion Wave Along a Northern California Littoral Cell.

Author

Warrick, J. A., Vos, K., Buscombe, D., Ritchie, A. C., and Curtis, J. A.

Subjects

SHORELINES, BEACH erosion, LITTORAL drift, SEDIMENT transport, CLIMATE extremes, RIVER sediments, SEDIMENTS, LANDFORMS, TWENTIETH century

Abstract

The northern California littoral cell of the Klamath River, which is a mixed rocky and sandy system with significant shoreline curvature, was investigated by examining ∼40 yr of satellite‐derived shoreline positions and historical records. We find that an accretion wave of sediment was initiated near the Klamath River mouth in the late 1980s and translated downcoast over the subsequent decades. The wave passed rapidly (∼2,500 m/yr) through a rocky coastal reach with more oblique wave directions and slowly through a sandy reach (∼200 m/yr) where wave crests approach at more normal angles. Within the sandy reach, the accretion wave extended over 200 m offshore, was ∼10 km long, incorporated 20 ± 6 million m3 of sediment, and averaged 1.3 ± 0.4 million m3/yr of longshore sediment transport over a 20‐yr interval. Diffusion of the accretion wave was observed, but the diffusivity coefficient (εobs ∼0.01 m2/s) was lower than values predicted by theory, which we attribute to net sediment transport convergence in the study area caused by the curvature of the shoreline. Examining historical records, we find that increased sediment discharge in the Klamath River occurred during the 20th century from industrial‐scale logging and climatic extremes. Thus, we hypothesize that increased river sediment discharge introduced new sediment to the littoral cell that initiated the observed accretion wave. These hypotheses can be tested with stratigraphic and mineralogic investigations of the broad study area beach that has formed during the past 150 years. Plain Language Summary: The existence of beaches along the world's coasts is dependent on the availability of sand or other sediment sources that build up these landforms. As sediment sources come and go over time, beaches may accrete or erode in response to these changes. These kinds of shoreline change patterns can be measured using new satellite‐based techniques that are especially valuable for coasts with limited ground‐based surveys. We applied these satellite‐based shoreline techniques to a portion of the northern California coast, which revealed that a massive body of sediment appeared on this coast in the 1980s, and that this sediment moved downcoast over the subsequent decades. The sediment stayed in a relatively continuous body—termed a coastal accretion wave—that extended 100's of meters offshore and several kilometers alongshore. The satellite measurements also allowed us to track the evolution of the shape and speed of this accretion wave and compare these results with physical conditions and sediment movement theory. Comparing with historical measurements, maps, and accounts, we hypothesize that sediment from the Klamath River has been a primary source of sediment to this coast, including the formation of the accretion wave and study area's broad beach. Key Points: An accretion wave of ∼20 million m3 of littoral sediment formed in the late 1980s and translated ∼15‐km downcoast over the next 30+ yearsAlongshore diffusion of the wave was less than predicted by theory, which is attributed to transport convergence from the shoreline curvatureIncreases in river sediment discharge from human impacts and climate extremes may have initiated the accretion wave [ABSTRACT FROM AUTHOR]

Published

2023

3. Estimating Suspended Sediment Concentration Using Turbidity in an Irrigation-Dominated Southeastern California Watershed.

Author

Peng Gao, Pasternack, Gregory B., Bali, Khaled M., and Wallender, Wesley W.

Subjects

TURBIDITY, SUSPENDED sediments, PARTICLE size distribution, ARID regions, WATERSHEDS

Abstract

This study investigates the feasibility of using turbidity (T) as a surrogate for suspended sediment concentration (C) in an irrigation-dominated watershed in southeastern California. A nonlinear T–C relationship was developed and evaluated using two independent sets of data obtained by physical sampling and laboratory turbidimeter. The relationship was interpreted in terms of the heterogeneous particle size distribution in the samples. The effects of spatial and temporal variation of particle sizes and water colors on the relationship were examined. Further, possible effects of laboratory procedures on the relationship such as time delay of sample measurement and calibration of T for C using lab-prepared samples were analyzed. The study showed that the variation of particle size distribution is the key factor controlling the T–C relationship. Water color and time delay for sample analysis did not significantly affect the turbidity values, whereas laboratory procedures may mislead the T–C relationship. It is concluded that turbidity may be a surrogate for suspended sediment concentration in such irrigation-dominated watersheds in arid regions, though the T–C relationship has to be established with care. [ABSTRACT FROM AUTHOR]

Published

2008

4. Submarine landslides in the Santa Barbara Channel as potential tsunami sources.

Author

Greene, H. G., Murai, L. Y., Watts, P., Maher, N. A., Fisher, M. A., Paull, C. E., and Eichhubl, P.

Subjects

LANDSLIDES, GEOLOGICAL basins, SLOPES (Soil mechanics), TSUNAMIS, SUBMARINE topography

Abstract

Recent investigations using the Monterey Bay Aquarium Research Institutes (MBARI) Remotely Operated Vehicles (ROVs) "Ventana" and "Tiburon" and interpretation of MBARI's EM 300 30 kHz multibeam bathymetric data show that the northern flank of the Santa Barbara Basin has experienced massive slope failures. Of particular concern is the large (130 km²) Goleta landslide complex located off Coal Oil Point near the town of Goleta, that measures 14.6-km long extending from a depth of 90m to nearly 574m deep and is 10.5 km wide. We estimate that approximately 1.75 km³ has been displaced by this slide during the Holocene. This feature is a complex compound submarine landslide that contains both surfical slump blocks and mud flows in three distinct segments. Each segment is composed of a distinct head scarp, down-dropped head block and a slide debris lobe. The debris lobes exhibit hummocky topography in the central areas that appear to result from compression during down slope movement. The toes of the western and eastern lobes are well defined in the multibeam image, whereas the toe of the central lobe is less distinct. Continuous seismic reflection profiles show that many buried slide debris lobes exist and comparison of the deformed reflectors with ODP Drill Site 149, Hole 893 suggest that at least 200 000 years of failure have occurred in the area (Fisher et al., 2005a). Based on our interpretation of the multibeam bathymetry and seismic reflection profiles we modeled the potential tsunami that may have been produced from one of the three surfical lobes of the Goleta slide. This model shows that a 10m high wave could have run ashore along the cliffs of the Goleta shoreline. Several other smaller (2 km² and 4 km²) slides are located on the northern flank of the Santa Barbara Basin, both to the west and east of Goleta slide and on the Conception fan along the western flank of the basin. One slide, named the Gaviota slide, is 3.8 km², 2.6 km long and 1.7 km wide. A distinct narrow scar extends from near the eastern head wall of this slide for over 2 km eastward toward the Goleta slide and may represent either an incipient failure or a remnant of a previous failure. Push cores collected within the main head scar of this slide consisted of hydrogen sulfide bearing mud, possibly suggesting active fluid seepage and a vibra-core penetrated ∼ 50 cm of recent sediment overlying colluvium or landslide debris confirming the age of ∼300 years as proposed by Lee et al. (2004). However, no seeps or indications of recent movement were observed during our ROV investigation within this narrow head scar indicating that seafloor in the scar is draped with mud. [ABSTRACT FROM AUTHOR]

Published

2006

5. Large-scale Basement-involved Landslides, California Continental Borderland.

Author

Legg, M. R. and Kamerling, M. J.

Subjects

SEISMIC waves, TSUNAMIS, MELANGES (Petrology), CLIFFS, SEDIMENTOLOGY

Abstract

— Large seafloor relief, shallow metamorphic basement, and seismic activity in the California Continental Borderland combine to produce major submarine slides capable of generating local tsunamis. The Catalina Schist basement complex of the Borderland contains melange units, faults between metamorphic facies, and foliation derived from a history of deep subduction underthrusting and subsequent tectonic exhumation along regional low-angle fault systems. Neogene volcanic and sedimentary rocks covered the exhumed metamorphic basement forming an interface with a strong contrast in material properties. Neogene transtensional block-faulting formed steep escarpments that cut through and elevated the low-angle detachment surface, providing slip surfaces with free faces susceptible to failure along the rheological boundary. Two basement-involved slope failure examples west of San Diego are described, including large block-glides and progressive rotational slumps along the steep northeast-facing Thirtymile Bank escarpment and along the southwest flank of Fortymile Bank. [ABSTRACT FROM AUTHOR]

Published

2003