Your search keyword '"Elana L. Leithold"' showing total 17 results

1. Repeated megaturbidite deposition in Lake Crescent, Washington, USA, triggered by Holocene ruptures of the Lake Creek-Boundary Creek fault system

Author

Audrianna F. Pollen, Elana L. Leithold, Karl W. Wegmann, Catelyn Joyner, and DelWayne R. Bohnenstiehl

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Sediment, Geology, Fault (geology), 010502 geochemistry & geophysics, 01 natural sciences, Archaeology, Deposition (geology), Stratigraphy, Lacustrine deposits, Holocene, 0105 earth and related environmental sciences

Abstract

Lake Crescent, a 180-m-deep, glacially carved lake located on the Olympic Peninsula in western Washington, USA, overlies the Lake Creek-Boundary Creek fault zone, a system of structures with at least 56 km of late Pleistocene to Holocene surface rupture. Investigation of the lake’s sediment, including a reflection seismic survey and analysis of piston cores, reveals evidence that the fault beneath the lake has ruptured four times in the past ∼7200 years, producing unusually thick deposits termed megaturbidites. The earthquakes triggered rockslides that entered the lake and caused displacement waves (lake tsunamis) and seiches, most recently ca. 3.1 ka. Seismic reflection results from beneath the depth of core penetration reveal at least two older post-glacial ruptures that are likely to have similarly affected the lake. The stratigraphy of Lake Crescent provides insight into the behavior of a fault system that partially accommodates regional clockwise rotation and contraction of the northern Cascadia forearc through oblique dextral shear, and highlights the potential for disruption to critical infrastructure, transportation corridors, and industry on the North Olympic Peninsula during future surface-rupturing earthquakes. Our results illustrate the potential synergism between lacustrine paleoseismology and fault-scarp trench investigations. More precise dating of strong earthquake shaking afforded by continuous accumulation of lake sediment improves earthquake histories based on trenched fault scarp exposures, which are commonly poorly dated.

Published

2019

2. Slope failures within and upstream of Lake Quinault, Washington, as uneven responses to Holocene earthquakes along the Cascadia subduction zone

Author

Ryan O'Grady, DelWayne R. Bohnenstiehl, Stephen G. Smith, Anders Noren, Elana L. Leithold, and Karl W. Wegmann

Subjects

geography, Disturbance (geology), geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Subduction, 010502 geochemistry & geophysics, 01 natural sciences, Arts and Humanities (miscellaneous), Stratigraphy, Aggradation, Subaerial, Period (geology), General Earth and Planetary Sciences, Geology, Holocene, Seismology, Channel (geography), 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Investigation of Lake Quinault in western Washington, including a reflection seismic survey, analysis of piston cores, and preliminary mapping in the steep, landslide-prone Quinault River catchment upstream of the lake, reveals evidence for three episodes of earthquake disturbance in the past 3000 yr. These earthquakes triggered failures on the lake’s underwater slopes and delta front, as well as subaerial landsliding, partial channel blockage, and forced fluvial sediment aggradation. The ages of the three Lake Quinault disturbance events overlap with those of coseismically subsided, coastal marsh soils nearby in southwest Washington that are interpreted to record ruptures of the Cascadia megathrust. Absent from Lake Quinault, however, are signals of obvious disturbance from five additional subduction earthquakes inferred to have occurred during the period of record. The lack of evidence for these events may reflect the limitations of the data set derived from the detrital, river-dominated lake stratigraphy but may also have bearing on debates about segmentation and the distribution of slip along the Cascadia subduction zone during prior earthquakes.

Published

2017

3. MID-HOLOCENE EARTHQUAKE-TRIGGERED LANDSLIDES CHANGED DRAINAGE PATTERS AND FORCED GENETIC DRIFT IN A POPULATION OF RAINBOW TROUT AT LAKE CRESCENT ON THE OLYMPIC PENINSULA, WASHINGTON STATE

Author

Elana L. Leithold and Karl W. Wegmann

Subjects

geography, education.field_of_study, geography.geographical_feature_category, Oceanography, Genetic drift, Peninsula, Population, Rainbow trout, Landslide, Drainage, education, Geology, Holocene

Published

2019

4. Signals of watershed change preserved in organic carbon buried on the continental margin seaward of the Waipaoa River, New Zealand

Author

L. B. Childress, Benjamin R. Brulet, Alan R. Orpin, Clark R. Alexander, Elana L. Leithold, Michael Marden, Steven A. Kuehl, and Neal E. Blair

Subjects

geography, geography.geographical_feature_category, Continental shelf, Bedrock, Geochemistry, Sediment, Geology, Mass wasting, Oceanography, Continental margin, Geochemistry and Petrology, Alluvium, Sedimentary rock, Holocene

Abstract

Holocene sediments buried on the continental shelf seaward of the Waipaoa River, northeastern New Zealand, preserve a stratigraphic record of terrestrial environmental change. The well characterized, long-term record of storms, volcanism, and human disturbance in this region provides an opportunity to examine how such changes are reflected in the character of organic carbon (OC) buried on the continental margin. Complimentary evidence obtained from analyses of the 14 C content and the elemental and stable carbon isotopic composition of different sedimentary fractions, including charcoal, wood, and clay-sized isolates, indicates that these perturbations led to mobilization of OC components with variable storage histories in the watershed. Charcoal transported in the modern Waipaoa River and buried in offshore depocenters includes a highly aged component that has apparently been slowly released from storage in soil or alluvial terraces. The charcoal fraction ages become dramatically younger in sediments deposited after the Taupo volcanic eruption (1717 cal yr BP) and then Polynesian settlement (ca. 700 cal yr BP), both signaling biomass burning. The mean age of woody plant fragments and clay-bound OC deposited on the shelf also varies over time, with older material having accumulated in the middle Holocene and since human occupation. Deposition of older-than-average wood fragments and clay-bound OC between about 5 and 3.6 kyr BP correlates with evidence for a period of increased storm frequency in the region and may reflect the enhanced delivery of aged soil and sedimentary rock mobilized from hill slopes via earthflows and/or deep seated landslides. Similarly, the deposition of older wood and clay-bound OC commensurate with the first anthropogenic disturbance ca. 700 years ago is consistent with accelerated mass wasting due to deforestation. At the same time, a change in the elemental and stable isotopic composition of bulk and clay-bound OC buried on the shelf may reflect increased marine primary productivity and/or mobilization of OC from deep levels in soil profiles. Deforestation of the Waipaoa headwaters by European settlers beginning in the middle 19th century is evinced by a sharper rise in the age of clay associated OC buried offshore. Today, deep gully incision into fractured sedimentary bedrock is a major source of sediment and kerogen to the river, and this process has left its mark on the age of sedimentary OC delivered to the adjacent margin.

Published

2013

5. Fingerprinting the sources of suspended sediment delivery to a large municipal drinking water reservoir: Falls Lake, Neuse River, North Carolina, USA

Author

Mark T. Voli, Karl W. Wegmann, Elana L. Leithold, DelWayne R. Bohnenstiehl, Christopher L. Osburn, and Viktor O. Polyakov

Subjects

Hydrology, geography, geography.geographical_feature_category, Stratigraphy, Sediment, STREAMS, Total maximum daily load, Tributary, Erosion, Environmental science, Water quality, Bank, Nonpoint source pollution, Earth-Surface Processes

Abstract

We employ a geochemical-fingerprinting approach to estimate the source of suspended sediments collected from tributaries entering Falls Lake, a 50-km2 drinking water reservoir on the Neuse River, North Carolina, USA. Many of the major tributaries to the lake are on North Carolina’s 303(d) list for impaired streams, and in 2008, the lake was added to that list because of high values of turbidity, likely sourced from tributary streams. Suspended sediments were collected from four streams with a time-integrated sampler during high-flow events. In addition, composite sediment samples representing potential sources were collected from stream banks, forests, pastures, construction sites, dirt and paved roads, and road cuts within tributary basins. Radiocarbon dating and magnetic susceptibility measurements were used to determine the origin of stream bank alluvial deposits. Sediment samples were analyzed for the concentrations of 55 elements and two radionuclides in order to identify tracers capable of distinguishing between potential sediment sources. The relative sediment source contributions were determined by applying a Monte Carlo simulation that parameterized the geochemical tracer data in a mixing model. Radiocarbon and magnetic susceptibility measurements confirmed the presence of “legacy” sediment in the Ellerbe and New Light Creek valley bottoms. Mixing model results demonstrate that stream bank erosion is the largest contributor to the suspended sediment load in New Light Creek (62%), Ellerbe Creek (58%), and Little Lick Creek (33%), and is the second largest contributor in Lick Creek (27%) behind construction sites (43%). We find that stream bank erosion is the largest nonpoint source contributor to the suspended sediment load in three of the four catchments and is therefore a significant source of turbidity in Falls Lake. The presence of legacy sediment appears to coincide with increased contributions from stream bank erosion in Ellerbe and New Light creeks. Active construction sites and timber harvesting were also significant sources of suspended sediment. Water quality mitigation efforts need to consider nonpoint-source contributions from stream bank erosion of valley bottom sediments aggraded after European settlement.

Published

2013

6. LACUSTRINE PALEOSEISMOLOGY FROM LAKE CRESCENT CONFIRMS MULTIPLE HOLOCENE RUPTURES OF THE LAKE CREEK – BOUNDARY CREEK FAULT ZONE IN RESPONSE TO NORTHWARD CONVERGENCE AND CLOCKWISE ROTATION OF THE NORTHERN OLYMPIC PENINSULA, WASHINGTON

Author

Karl W. Wegmann, Catelyn Joyner, DelWayne R. Bohnenstiehl, Audrianna F. Pollen, and Elana L. Leithold

Subjects

Paleontology, geography, geography.geographical_feature_category, Peninsula, Boundary (topology), Paleoseismology, Convergence (relationship), Clockwise, Geology, Holocene

Published

2017

7. A HOLOCENE EARTHQUAKE RECORD FROM LAKE CRESCENT, OLYMPIC PENINSULA, WASHINGTON

Author

DelWayne R. Bohnenstiehl, Elana L. Leithold, and Karl W. Wegmann

Subjects

geography, geography.geographical_feature_category, Peninsula, Archaeology, Holocene, Geology

Published

2017

8. Terrestrial sources and export of particulate organic carbon in the Waipaoa sedimentary system: Problems, progress and processes

Author

Elana L. Leithold, Mike Page, Neal E. Blair, H.L. Brackley, Noel A. Trustrum, and L. B. Childress

Subjects

Total organic carbon, Hydrology, geography, geography.geographical_feature_category, Floodplain, Geochemistry, Geology, Particulates, Oceanography, chemistry.chemical_compound, chemistry, Geochemistry and Petrology, Isotopes of carbon, Kerogen, Alluvium, Sedimentary rock, Colluvium

Abstract

The composition of particulate organic carbon in sedimentary systems can provide information concerning sources of materials and their history. The NSF-MARGINS Source to Sink study of the Waipaoa Sedimentary System in New Zealand provides a platform to calibrate the particulate organic carbon sedimentary record by linking chemical characteristics to terrestrial and marine sedimentary processes. This report is a preliminary evaluation of the available organic carbon concentration, elemental C/N ratio and C-isotopic composition data for the terrestrial portion of the system. Samples analyzed were rocks, soils, floodplain sediments and riverine suspended sediments. Measurements confirm previous conclusions that a portion of the riverine particulate organic carbon is derived from sedimentary rocks. The rock C (kerogen) concentration is relatively invariant (~ 0.25%) from rock source, to riverine and floodplain sediments. The non-rock C is derived from C3 vegetation in most of the watershed, the exception being the floodplain in which local C4 plant inputs are detected. The non-rock organic carbon has a mean 14C-age of approximately 1000 years, which reflects a mixture of modern and aged components. The presence of aged non-rock C, which is chronic in its supply to the river, indicates storage of particulates within the watershed. Remobilized colluvial and alluvial deposits are among the possible sources. Systematic differences are found between δ13C databases generated by various groups. While there may be natural explanations for these differences, methodological artifacts have to be considered. Standardization of methods that cross source-to-sink boundaries is recommended.

Published

2010

9. Dispersal and transformation of organic carbon across an episodic, high sediment discharge continental margin, Waipaoa Sedimentary System, New Zealand

Author

Elizabeth A. Canuel, James H. Johnston, Kevin R. Tate, Neal E. Blair, Lionel Carter, Noel A. Trustrum, Elana L. Leithold, and H.L. Brackley

Subjects

Hydrology, Total organic carbon, geography, geography.geographical_feature_category, Floodplain, Discharge, Terrigenous sediment, Continental shelf, fungi, Sediment, Geology, Oceanography, Continental margin, Geochemistry and Petrology, Sedimentary rock

Abstract

The rivers that drain active, collisional margins of the southwest Pacific deliver up to 35% of particulate organic carbon (POC) to the world ocean, and are a key component of the global organic carbon flux. However, knowledge of the fate of terrestrial POC in the ocean is both limited and necessary for quantifying terrestrial and coastal ocean carbon budgets. Here, the fate of terrestrial POC is determined off the high discharge, Waipaoa River (sediment yield 15 Mt y − 1 ) based on a transect of seven cores from the river floodplain to the adjacent continental shelf and slope. Total organic carbon (%TOC), δ 13 C, 14 C, C/N ratios and lipid biomarker compounds were used to determine biogeochemical characteristics of surface sediments from terrestrial source to marine sink, and how these characteristics vary with river discharge. Complementary to surface sediments, down-core characteristics of three multi-cores covering the shelf and slope regions were used to identify perturbations in sediment supply via major floods. The presence of flood deposits allows us to compare their OC characteristics with non-flood sediment, thereby helping address the question of how flood events in the river catchment affect the transfer and fate of terrestrial OC through the marine environment. Results from this study show that as surface sediments are physically and biologically processed across the continental margin, they gain a marine signature. Biomarker analyses of surface samples show decreases in terrigenous vascular plant sources with increasing distance offshore. Biomarkers also demonstrate that terrestrial OC is being transferred across the continental margin, with plant sterols, long-chain alcohols and long-chain fatty acids (biomarkers indicative of vascular plants) persisting as far offshore as the mid-continental slope. In contrast to ambient conditions represented by surface sediments, rapid delivery by floods allows for more complete transfer of terrestrial carbon to the marine environment. A 1–10 cm thick flood layer preserved from Cyclone Bola (March 1988) contains a significant amount of terrestrially-sourced OC which subsequently was rapidly buried by sediments delivered during less extreme conditions.

Published

2010

10. MEGATURBIDITES IN LAKE CRESCENT, WASHINGTON—SEDIMENTARY RECORD OF REPEATED CATASTROPHIC EVENTS TRIGGERED BY SURFACE RUPTURE OF THE LAKE CREEK–BOUNDARY CREEK FAULT

Author

DelWayne R. Bohnenstiehl, Catelyn Joyner, Karl W. Wegmann, Audrianna F. Pollen, and Elana L. Leithold

Subjects

Surface rupture, geography, geography.geographical_feature_category, Boundary (topology), Sedimentary rock, Fault (geology), Geology, Seismology

Published

2016

11. Sedimentation and carbon burial on the northern California continental shelf: the signatures of land-use change

Author

Todd N. Creamer, Neal E. Blair, David W. Perkey, and Elana L. Leithold

Subjects

chemistry.chemical_classification, Total organic carbon, geography, geography.geographical_feature_category, Continental shelf, Sediment, Geology, Aquatic Science, Sedimentation, Oceanography, Continental margin, chemistry, Isotopes of carbon, Organic matter, Sedimentary rock

Abstract

The burial of organic carbon (OC) on continental margins is strongly coupled to the supply and accumulation of inorganic mineral particles. It follows that carbon burial on the margins should be impacted by changes in riverine sediment delivery, yet these impacts have not been well documented. In this study, an ∼2000-year record of sedimentation and carbon burial on the continental shelf offshore from the Eel River in northern California was examined. The record reveals a 6–11-fold increase in the rate of sediment accumulation on the mid-shelf beginning about 1955, and a concomitant decrease in grain size and increase in flood-layer preservation. At the same time, the age of buried wood fragments abruptly decreased and their stable carbon isotopic composition became enriched in 13C. We argue that these changes can be explained largely as the result of altered land use in the Eel watershed during the past century and its impacts on shelf sediment dispersal processes. Sedimentary OC on the Eel shelf consists primarily of discrete wood fragments associated with coarse-silt- and sand-sized particles, and of organic matter strongly bound to clay-sized mineral grains. The clay fraction is a particularly sensitive recorder of environmental change in the Eel system. Above the 1955 horizon, the clay fraction shows an abrupt decrease in OC concentration and loading (OC content normalized to particle surface area) attendant with the increased accumulation rate. Kerogen carbon constitutes a relatively constant proportion of the clay-associated OC throughout the ∼2000-year record. Increases in mass wasting and input of bedrock material following the onset of intensive industrial logging in the Eel watershed may have resulted in a lower loading of terrestrial plant OC in the clay fraction deposited after 1955 as suggested by isotopic mass balance calculations. The Eel River is representative of small mountainous watersheds worldwide that deliver a major portion of the sediment and carbon flux to the margins and that have been strongly impacted by land-use change during the past century. Our results suggest that such changes leave a distinctive mark in both the sedimentological and geochemical records preserved offshore.

Published

2005

12. From bedrock to burial: the evolution of particulate organic carbon across coupled watershed-continental margin systems

Author

Neal E. Blair, Elana L. Leithold, and Robert C. Aller

Subjects

Total organic carbon, chemistry.chemical_classification, Hydrology, geography, geography.geographical_feature_category, Bedrock, Earth science, Sediment, General Chemistry, Oceanography, Sedimentary depositional environment, chemistry.chemical_compound, chemistry, Continental margin, Organic geochemistry, Kerogen, Environmental Chemistry, Organic matter, Geology, Water Science and Technology

Abstract

Deltas sequester nearly half of the organic carbon (OC) buried in the marine environment. The composition of the buried organic matter reflects both watershed and seabed processes. A conceptual model is presented that describes the evolution of particulate organic carbon (POC) as it travels from its terrestrial source to its burial at sea. Alterations to the POC occur primarily in bioactive reservoirs, such as soils and the surface mixed layer (SML) of the seabed, where new organic matter can be added and older material degraded. Bypassing or rapid passage through the reservoirs is a key parameter because it avoids change. The Eel River of northern California and the Amazon River systems illustrate the importance of reservoir transit time and storage in determining the character of POC delivered to the continental margin. The Eel exemplifies a bypass system. Mass-wasting processes on land deliver unaltered bedrock along with OC derived from extant vegetation directly to the river channel without significant storage in soils. Rapid burial on the shelf occurs as a result of flood events. As a consequence, the buried material appears to be a simple mixture of carbon derived from kerogen (bedrock C), and modern terrestrial and marine sources. This is predicted to be a characteristic of the many similar short rivers on active margins that supply >40% of the fluvial sediment to the world's ocean. Extensive storage and processing of OC in lowland soils is a characteristic of the large Amazon watershed. Upland POC compositions are either overprinted or replaced by lowland sources. Upon delivery to the shelf, over half of the riverine POC is lost as a result of residence in sediment layers that are periodically reworked over time scales of days to months. The addition of fresh reactive marine OC, exposure to oxygen, and the regeneration of metal oxidants during resuspension events fuel the oxidation of the riverine organic matter. The nature of the watershed-shelf processes likely produce a complex mixture of organics possessing a continuum of ages and reactivities. The model illustrates the need to develop tools to measure residence times of particles in the various reservoirs so that the behavior of POC can be calibrated as it moves through a sedimentary system. The ultimate goal is to be able to use the organic geochemistry of soils and sediments to quantitatively infer the history of processes that determine both the composition and amount of POC present in different depositional environments.

Published

2004

13. The persistence of memory: the fate of ancient sedimentary organic carbon in a modern sedimentary system

Author

Shawn T Ford, Jennifer C Holmes, Elana L. Leithold, Neal E. Blair, Kelly A Peeler, and David W. Perkey

Subjects

Total organic carbon, chemistry.chemical_classification, geography, geography.geographical_feature_category, Earth science, Bedrock, Sediment, Paleontology, chemistry, Geochemistry and Petrology, Soil water, Erosion, Organic matter, Sedimentary rock, Geology, Seabed

Abstract

The cycle of organic carbon burial and exhumation moderates atmospheric chemistry and global climate over geologic timescales. The burial of organic carbon occurs predominantly at sea in association with clay-sized particles derived from the erosion of uplifted continental rocks. It follows that the history of the fine-grained particles on land may bear on the nature of the organic carbon buried. In this study, the evolution of clay-associated organic matter was followed from bedrock source to the seabed in the Eel River sedimentary system of northern California using natural abundance 13C and 14C tracers. Approximately half of the fine-grained organic carbon delivered to the shelf is derived from ancient sedimentary organic carbon found in the uplifted Mesozoic-Tertiary Franciscan Complex of the watershed. The short residence time of friable soils on steep hill slopes, coupled with rapid sediment accumulation rates on the shelf-slope, act to preserve the ancient organic carbon. A comparable quantity of modern organic carbon is added to particles in the watershed and on the shelf and slope. The bimodal mixture of ancient and modern C in soils and sediments may be characteristic of many short, mountainous rivers. If the Eel River chemistry is typical of such rivers, more than 40 Tg of ancient organic C may be delivered to the world’s oceans each year. A flux of that magnitude would have a significant influence on marine and global C-cycles.

Published

2003

14. Watershed control on the carbon loading of marine sedimentary particles

Author

Elana L. Leithold and Neal E. Blair

Subjects

Total organic carbon, geography, geography.geographical_feature_category, Terrigenous sediment, Continental shelf, fungi, Geochemistry, Sediment, chemistry.chemical_element, Continental shelf pump, Oceanography, Continental margin, chemistry, Geochemistry and Petrology, Sedimentary rock, Carbon, Geology

Abstract

Previous investigations of the factors governing organic carbon burial on continental margins have pointed toward the important, apparently protective association of carbon with mineral particles. These studies have also revealed dramatic transformations of carbon-particle relationships at the land-sea interface. Riverine particles in some settings lose a large portion of their loads of sorbed terrestrial carbon upon discharge to the ocean and gradually reload to similar levels with marine carbon. The Eel River in northern California and the adjacent continental shelf were selected as an ideal system to investigate the rates of these processes. The river is episodically subject to large floods, and the shelf stratigraphy preserves a record of the resultant large pulses of sediment and carbon input to the marine environment. Carbon isotopic, carbon to nitrogen, and carbon to surface area ratios of particles in flood deposits were expected to reflect the rapid unloading of terrestrial carbon from discharged particles, whereas nonflood sediments that have accumulated at slower rates on the shelf were expected to carry higher loads of marine carbon. Our results indicate, however, that particles on the Eel shelf have retained their loads of terrigenous carbon, and that a significant portion of the particle-sorbed carbon buried on the shelf is kerogen derived from the Mesozoic-Tertiary Franciscan Complex. We hypothesize that rates of uplift and mass wasting in the Eel watershed and rates of particle delivery to and burial on the continental shelf, are so rapid that kerogen is not completely oxidized and is recycled instead. The loading of carbon on clay-sized particles delivered to the shelf, moreover, is dependent on river discharge and may reflect the relative importance of different mass wasting processes during precipitation events of varying intensity. The Eel River system is likely to be representative of other small, mountainous rivers and indicates that processes on land may play an important role in governing the amount and character of carbon being buried on the continental margins.

Published

2001

15. Deposition and modification of a flood layer on the northern California shelf: lessons from and about the fate of terrestrial particulate organic carbon

Author

Rebecca S. Hope and Elana L. Leithold

Subjects

Total organic carbon, Hydrology, geography, geography.geographical_feature_category, Flood myth, Continental shelf, fungi, food and beverages, Sediment, Geology, Soil carbon, Oceanography, Deposition (geology), Continental margin, Geochemistry and Petrology, parasitic diseases, Benthic boundary layer

Abstract

The 1995 flood of the Eel River in northern California provided an opportunity to follow the short-term history of riverine particulate matter on a continental shelf. Particulate organic carbon, including both vascular plant debris and soil carbon, was utilized as a tracer of the distribution and modification of the shelf flood deposit. These components were sorted during initial emplacement of the deposit, both in the river plume and in the benthic boundary layer. During the 8 months following the flood, lateral transport, shallow burial, and bioturbation contributed to spatial changes in the amount and character of carbon in the flood deposit. Study of the deposit suggests that this and previous flood layers may be preserved in the shelf and upper slope stratigraphic record as clay-rich beds with relatively high carbon to nitrogen ratios and more negative δ13C values than background, non-flood sediment. Concentrations of vascular plant debris are locally characteristic of such layers, and may serve as distinctive stratigraphic markers. Investigation of organic carbon in the 1995 flood layer on the Eel River shelf provides insight into the fate of terrestrial particulate carbon on continental margins in general. Flooding of the Eel River, and of similar river systems draining mountainous terrains, introduces large quantities of terrestrial carbon to the marine environment and may favor the preservation of both terrestrial and marine carbon. The abundant woody vascular plant debris discharged during floods is especially likely to survive oxidation and sulfate reduction in the shallower zones of the seabed. This study reveals the dominant role that physical and biological processes may play in attenuating the terrestrial organic-carbon signal on shelves over monthly to yearly time scales.

Published

1999

16. Following the Fate of Flood Layers on the Northern California Continental Margin

Author

Elana L. Leithold

Subjects

geography, Oceanography, geography.geographical_feature_category, Continental margin, Flood myth, Continental shelf, Earth science, Stratification (water), Geology

Abstract

The long-term goal of this research is to contribute toward our understanding of the processes by which strata are formed on continental margins. In particular, this research is aimed at elucidating the processes that control the distribution, characteristics, and modification of event layers on continental shelves.

Published

1997

17. Sedimentation, sea-level change, and tectonics on an early Pleistocene continental shelf, northern California

Author

Joanne Bourgeois and Elana L. Leithold

Subjects

Shore, geography, geography.geographical_feature_category, Continental shelf, Geology, Subsidence, Storm, Deposition (geology), Sedimentary depositional environment, Paleontology, Tectonics, Oceanography, Progradation

Abstract

The Rio Dell Formation was deposited in a tectonically active area during a time of fluctuating eustatic sea-level. Detailed interpretation of Rio Dell shelf sediments, facilitated by comparison to the nearby, analogous, modern Eel River shelf, has proved a vital tool for decoding the record of these influences. Understanding of the nature and relative roles of processes on the modern and ancient shelf, including those associated with storms and with river floods, not only allows for detailed paleobathymetric reconstruction of the ancient sequence, but also for recognition of relatively subtle effects of syndepositional tectonism. Shelf sediments of the Rio Dell Formation comprise four depositional sequences bounded by thin, submarine condensed sections. The condensed sections formed during periods of rapid, probably largely eustatic, sea-level rise. The sequences each record progradation of the shelf, predominantly during sea-level highstands. Paleobathymetric reconstruction provides the basis for interpretation of the magnitude of local, relative sea-level changes within and between the sequences. Subsidence of the Rio Dell shelf apparently played a role in recorded local sea-level fluctuations, as did eustasy. Subsidence ("geohistory") analysis of the sequence indicates that the shelf was subsiding throughout its existence, due not only to sediment loading but also due to tectonism. The analysis points to a period of rapid shelf subsidence, accompanied by onland uplift, between about 1.3 and 1.2 Ma. An increase in subsidence rates after about 1.3 Ma apparently caused an increase in Rio Dell shelf gradient, which changed the balance between flood and storm processes on the middle shelf. Increased shelf inclination evidently resulted in restriction of storm-wave reworking to a narrower zone extending from the shoreline, whereas distance from shoreline to the shelf area most influenced by river-flood deposition remained unchanged. The resultant increased segregation of flood and storm effects caused a fining of background grain-size distributions at mid-shelf sites.

Published

1989