Your search keyword '"Cecilia M. G. McHugh"' showing total 50 results

1. Investigating the Strength of the Indian Monsoons during Climate Extremes with Stable Isotope Records in Corals

Author

Dhiman R. Mondal, Richard A. Mortlock, Hannah Varkey, and Cecilia M. G. McHugh

Subjects

Monsoon of South Asia, Oceanography, δ18O, Coral, Ice age, General Earth and Planetary Sciences, Environmental science, Glacial period, Climate state, Precipitation, Monsoon, General Environmental Science

Abstract

The Indian monsoon affects the lives of over a billion inhabitants living in southern Asia via the hy-drological cycle. Agriculture on land and freshwater discharge into the ocean. This discharge and nutri-ent cycling are tied with the monsoon cycles that di-rectly impact society and the economy. Previous studies have demonstrated a strong connection be-tween the strength of the Indian monsoon and the cooling of the North Atlantic during climate ex-tremes, such as during the last glacial period 20,000 years ago, and the Little Ice Age (~1300-1870 A.D.). In our study, we compare the relative strength of the monsoon during two different climate states: the Lit-tle Ice Age (LIA) and the modern (2015) with proxy measurements obtained in surface corals from Saint Martin’s Island, Southeast Bangladesh. We used the oxygen-isotope 18O/16O ratio (δ18Oc) of coralline aragonite (CaCO3) to reconstruct changes in the δ18O of seawater (δ18Ow) attributed to freshening from monsoon rains. During both climate states, corals recorded large variations in δ18Oc (up to 2 parts per thousand or ‰). We attribute these changes, in part, to local salinity changes which are reflected by variability in δ18Ow from local riverine discharge. While our records only represent 5-year snapshots and may not be representative of the av-erage climate state, this data does not support that the monsoon was substantially weaker during the LIA compared to the modern. In this study, the coral records indicate subtle patterns of isotopic compo-sition as a function of precipitation and temperature variability, serving as a preliminary for further study through longer records lasting a century. Beyond this, it would better our understanding of interac-tions between extremes in temperature and climate systems.

Published

2021

2. Deformation, earthquakes and tsunamis along thickly sedimented subduction: Arakan segment of the Sunda Arc

Author

Leonardo Seeber, Syed Humayun Akhter, Michael S. Steckler, Cecilia M. G. McHugh, and Nickolas Dubin

Subjects

Arc (geometry), Subduction, Deformation (meteorology), Geology, Seismology

Abstract

Incoming sediment thickness and composition are primary factors in the morphology and shallow structure of subduction boundaries. Sediment thickness in the Indian Ocean increases SE to NW along the Sunda arc. From 15km where the boundary encounters the Ganges-Brahmaputra Delta (GBD). Here the accretionary prism broadens to the NW to >300 km wide. It is dominated by shallow-water to non-marine sediment. This segment also features a broad shallow megathrust overlain by linear anticlines rooted in splay faults. It is entirely above sea level and blind in its frontal part. This GBD segment transitions to a more familiar subduction structure and morphology along the submerged Arakan segment to the SE. The SE portion of this segment is characterized by larger splay faults that expose deep-water sediment with mud diapirism forming volcanoes and circular synclines. With increasing sediment input, the NW portion of the Arakan segment encroaches onto the GBD shelf. Both the SE and NW portions of the Arakan segment ruptured in the Mw>8.5 1762 tsunamigenic earthquake according to field and modeling evidence.Uplifted coral reefs and marine terraces along the Myanmar and Bangladesh coasts document a >500 km rupture in 1762. The uplift, ranging from 6 m to 2 m from south to north, has been linked to rupture on the megathrust and on shallow splays. Tsunami deposits are traced for ~10 km along the St. Martin’s Island anticline and for >40 km along the Teknaf peninsula. Microfossils and mollusk assemblages in these deposits are consistently of shallow water affinity and date the tsunami to 1762. This deposit covers only a small fraction of the inferred megathrust rupture. If it is representative of the total tsunami distribution, a local anticline may have been the main source. Evidence from live coral microatolls show uplift on St. Martin’s Island continuing 250 years after the earthquake. This motion could stem from continued anelastic deformation of the anticline updip of the rupture. More widely distributed evidence from sediment and corals could address questions about megathrust and splay behavior in 1762 and after. Plans include multichannel seismic surveying, high resolution subbottom profiling and 40 m long piston coring to compare the SE to NW shelf portions to the Arakan segment along the Myanmar and Bangladesh coasts. More generally, we aim to better understand subduction and geohazards along thickly sedimented systems.

Published

2021

3. Microatolls document the 1762 and prior earthquakes along the southeast coast of Bangladesh

Author

Dhiman R. Mondal, S. Mustaque, Cecilia M. G. McHugh, Syed Humayun Akhter, Michael S. Steckler, and Richard A. Mortlock

Subjects

Tectonic subsidence, 010504 meteorology & atmospheric sciences, Subduction, Coral, Anticline, Elevation, Microatoll, 010502 geochemistry & geophysics, Collision zone, 01 natural sciences, Geophysics, Seismic hazard, Seismology, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

In order to understand the seismic hazard associated with the Sunda megathrust along SE Bangladesh, it is necessary to document geologic evidence for the 1762 Arakan earthquake (M8.5–8.8) and prior events. Historical records indicated that the 1762 earthquake caused extensive damage along the Arakan segment of the Sunda subduction system, but geologic evidence for the earthquake farther north is necessary to better understand its associated seismic hazard to the heavily populated nation of Bangladesh. To document the paleoseismic history and understand ongoing tectonic deformation, we conducted detailed analyses of corals and microatolls in Saint Martin's Island, SE Bangladesh. The coral growth bands were studied, dated using U/Th systematics and their elevation was measured using high-precision GPS with RTX™ capability. The U/Th dating and >2 m of elevation differences between dead and living corals provide strong evidence of the coseismic uplift of 1762 Arakan earthquake. Based on annual banding patterns and reconstruction of the highest level of survival, coral microatolls indicate a tectonic subsidence rate of 2.2 ± 0.8 mm/yr prior to their uplift, consistent with elastic strain accumulation before the earthquake. In contrast, annual growth bands of a living coral microatoll indicate that Saint Martin's Island is presently experiencing uplift, at a rate of 1.8 ± 0.1 mm/yr. This suggests that the anticline underlying Saint Martin's Island is actively deforming following the earthquake. Our study also provides evidence for two additional earthquakes taking place in ~700 and ~1140 CE. These findings suggest a preliminary earthquake recurrence interval of ~500 years. Based on our results, the 1762 rupture can be extended from Faul Island (18°N) to Saint Martin's Island in SE Bangladesh (20.6°N). The motions documented from the corals suggest that this segment of the Arakan collision zone is storing sufficient energy to cause a future earthquake of M > 8.

Published

2018

4. Neogene siliciclastic deposition and climate variability on a carbonate margin: Australian Northwest Shelf

Author

Gabriel Tagliaro, Luc L. Lavier, Craig S. Fulthorpe, Stephen J. Gallagher, Cecilia M. G. McHugh, and Michelle A. Kominz

Subjects

Piacenzian, 010504 meteorology & atmospheric sciences, Fluvial, Geology, Late Miocene, 010502 geochemistry & geophysics, Oceanography, Neogene, 01 natural sciences, Paleontology, Geochemistry and Petrology, Paleoceanography, Passive margin, Sedimentary rock, Siliciclastic, 0105 earth and related environmental sciences

Abstract

The Bare Formation represents a unique episode of Neogene siliciclastic deposition on the carbonate-dominated Australian Northwest Shelf (NWS). Seismic interpretation coupled with age control from International Ocean Discovery Program (IODP) Expedition 356 Sites U1462, U1463 and U1464 allow us to constrain the timing of siliciclastic deposition and the associated sedimentary processes. The Bare Formation is preceded by middle to late Miocene shelf exposure and karstification (~12 Ma). Elongate sandbars deposits with small lobate deltas developed during the late Miocene. Fluvial deposition increased markedly in the Zanclean (5.3–3.6 Ma), resulting in development of a large wave dominated delta, with evidence of channels, comprising the thickest component of the Bare Formation. Siliciclastic input decreased in the Piacenzian (3.6–2.58 Ma), leading to margin retreat and final termination in the early Pleistocene (~2.39 Ma). The results correlate with regional climate and sedimentary records from Sites U1463 and U1464, which indicate an arid middle to late Miocene on the NWS, followed by a humid interval in the Zanclean and a return to arid conditions during the Piacenzian. We suggest that fluctuation of surface runoff patterns in the continental hinterland was the primary control on Bare Formation evolution. Sedimentary and climate transitions are linked to reorganization of Indian Ocean paleoceanography, accompanying northward migration of the Australian continent and progressive restriction of the Indonesian Throughflow.

Published

2018

5. Supercycle in great earthquake recurrence along the Japan Trench over the last 4000 years

Author

Toshiya Kanamatsu, Cecilia M. G. McHugh, Kazuko Usami, and Ken Ikehara

Subjects

Peak ground acceleration, Earthquake, 010504 meteorology & atmospheric sciences, lcsh:QE1-996.5, Paleoseismology, Slip (materials science), Supercycle, 010502 geochemistry & geophysics, Turbidite, 01 natural sciences, Coring, Sedimentary depositional environment, lcsh:Geology, Trench, Japan Trench, General Earth and Planetary Sciences, lcsh:Q, Biogeosciences, lcsh:Science, Geology, Seismology, 0105 earth and related environmental sciences

Abstract

On the landward slope of the Japan Trench, the mid-slope terrace (MST) is located at a depth of 4000–6000 m. Two piston cores from the MST were analyzed to assess the applicability of the MST for turbidite paleoseismology and to find out reliable recurrence record of the great earthquakes along the Japan Trench. The cores have preserved records of ~ 12 seismo-turbidites (event deposits) during the last 4000 years. In the upper parts of the two cores, only the following earthquakes (magnitude M ~ 8 and larger) were clearly recorded: the 2011 Tohoku, the 1896 Sanriku, the 1454 Kyotoku, and the 869 Jogan earthquake. In the lower part of the cores, turbidites were deposited alternately in the northern and southern sites during the periods between concurrent depositional events occurring at intervals of 500–900 years. Considering the characteristics of the coring sites for their sensitivity to earthquake shaking, the concurrent depositional events likely correspond to a supercycle that follows giant (M ~ 9) earthquakes along the Japan Trench. Preliminary estimations of peak ground acceleration for the historical earthquakes recorded as the turbidites imply that each rupture length of the 1454 and 869 earthquakes was over 200 km. The earthquakes related to the supercycle have occurred over at least the last 4000 years, and the cycle seems to have become slightly shorter in recent years. Earthquakes off the Sanriku coast forming the alternative deposition of turbidites in the two cores have released a part of accumulated slip, as indicated by the turbidites deposited in only one core. Decreases in the release of accumulated slip have possibly caused the recent shortening of the supercycle.

Published

2018

6. The sedimentary imprint of Pleistocene glacio-eustasy: Implications for global correlations of seismic sequences

Author

Cecilia M. G. McHugh, Peter Blum, Craig S. Fulthorpe, Koichi Hoyanagi, Gregory S. Mountain, and Kenneth G. Miller

Subjects

Paleontology, 010504 meteorology & atmospheric sciences, Pleistocene, Stratigraphy, Geology, Sedimentary rock, 010502 geochemistry & geophysics, 01 natural sciences, 0105 earth and related environmental sciences

Published

2017

7. High‐resolution chronology of sediment below <scp>CCD</scp> based on <scp>H</scp> olocene paleomagnetic secular variations in the <scp>T</scp> ohoku‐oki earthquake rupture zone

Author

Toshiya Kanamatsu, Kazuko Usami, Cecilia M. G. McHugh, and Ken Ikehara

Subjects

Paleomagnetism, 010504 meteorology & atmospheric sciences, Geomagnetic secular variation, Pyroclastic rock, 010502 geochemistry & geophysics, 01 natural sciences, Sedimentary depositional environment, Geophysics, Geochemistry and Petrology, Earthquake rupture, Tephra, Seismology, Geology, Holocene, Carbonate compensation depth, 0105 earth and related environmental sciences

Abstract

Using high-resolution paleomagnetic data, we examined the potential for obtaining precise ages from sediment core samples recovered from deep-sea basins close to rupture zones of the 2011 and earlier earthquakes off Tohoku, Japan. Obtaining detailed stratigraphic ages from deep-sea sediments below the calcium compensation depth (CCD) is difficult, but we found that the samples contain excellent paleomagnetic secular variation records to constrain age models. Variations in paleomagnetic directions obtained from the sediments reveal systematic changes in the cores. A stacked paleomagnetic profile closely matches the Lake Biwa data sets in southwest Japan for the past 7,000 years, one can establish age models based on secular variations of the geomagnetic field on sediments recovered uniquely below the CCD. Comparison of paleomagnetic directions near a tephra and a paleomagnetic direction of contemporaneous pyroclastic flow deposits acquired by different magnetization processes shows precise depositional ages reflecting the magnetization delay of the marine sediment record.

Published

2017

8. THE SEDIMENTARY AND ISOTOPIC SIGNATURE OF THE 2011 TOHOKU EARTHQUAKE AND TSUNAMI AND PRIOR EARTHQUAKES, JAPAN TRENCH

Author

Ken Ikehara, Leonardo Seeber, Michael Strasser, Kazuko Usami, Cecilia M. G. McHugh, Toshiya Kanamatsu, and McCain Moore

Subjects

Isotopic signature, Trench, Sedimentary rock, Geology, Seismology

Published

2019

9. EXTRACTING THE SEDIMENT RECORD OF MEGATHRUST RUPTURES IN THE JAPAN TRENCH THROUGH SCIENTIFIC OCEAN DRILLING

Author

Toshiya Kanamatsu, Troy Rasbury, Cecilia M. G. McHugh, Leonardo Seeber, Michael Strasser, Kazuko Usami, and Ken Ikehara

Subjects

Trench, Geochemistry, Drilling, Sediment, Geology

Published

2019

10. EXTRACTING THE RECORD OF STORMS FROM THE SEDIMENTS OF LONG ISLAND SOUND

Author

Cecilia M. G. McHugh, Frank O. Nitsche, Adam Kaiser, Michael Delligatti, and Timothy C. Kenna

Subjects

Oceanography, Storm, Long island sound, Geology

Published

2019

11. Remobilization of surficial slope sediment triggered by the A.D. 2011 Mw9 Tohoku-Oki earthquake and tsunami along the Japan Trench

Author

Marie-H. Cormier, Toshiya Kanamatsu, Richard F. Bopp, Cecilia M. G. McHugh, Kazuko Usami, and Leonardo Seeber

Subjects

Ground motion, 010504 meteorology & atmospheric sciences, Submarine, Geology, Slip (materials science), 010502 geochemistry & geophysics, 01 natural sciences, Seafloor spreading, law.invention, law, Nuclear power plant, Trench, Sedimentary rock, Aftershock, Seismology, 0105 earth and related environmental sciences

Abstract

The A.D. 2011 Tohoku-Oki M w 9 earthquake ruptured the megathrust up to the Japan Trench with a large displacement and caused a catastrophic tsunami. This study is the first to use short-lived radioisotopes, including those emitted by the damaged nuclear reactors at the Fukushima Daiichi nuclear power plant (Japan), to document the remobilization of the upper few centimeters of sediment as a highly significant process triggered by the earthquake and its aftershocks. Targeting the post-earthquake environment allowed characterization of the sedimentary signature of this event for a better understanding of paleoearthquakes in Japan and other tectonically active boundary areas. The results stem from 23 piston cores recovered by the 2013 expedition NT13-19 of the Japan Agency for Marine-Earth Science and Technology. We document submarine homogeneous muddy flow deposits that were triggered by ground motion in 2011. They are highly enriched with excess (xs) xs 210 Pb, requiring only centimeters-deep sediment remobilization over large areas of the seafloor. Some contain 134 Cs and 137 Cs radioisotopes derived from the Fukushima nuclear reactors, indicating that sedimentation persisted for at least 30 days after the main shock. We found these deposits at all sampling sites in an ∼5000 km 2 area of the seafloor in 4000–6000 m of water depth. The study area extends for ∼260 km parallel to the strike of the trench. The thickness of this "Tohoku layer" (3–200 cm) increases toward the zone of maximum megathrust slip, where deposits are thickest. These results demonstrate that the shaking of the seafloor above large megathrust ruptures near the trench remobilized surficial unconsolidated sediment for hundreds of kilometers. The characteristics of these deposits may typify deposits resulting from large fault slips like that of the Tohoku-Oki earthquake, but also other earthquake deposits, contributing to their identification in the sedimentary record globally.

Published

2016

12. Data report: revised Pleistocene age model based on a modified nannofossil bioevent and additional measurements of benthic foraminiferal oxygen and stable carbon isotope ratios from Hole U1352B, offshore Canterbury Basin, New Zealand

Author

T. Takeuchi, Peter Blum, Y. Tanaka, Koichi Hoyanagi, Masayuki Utsunomiya, Craig S. Fulthorpe, Cecilia M. G. McHugh, and M. Ikehara

Subjects

Oceanography, chemistry, Pleistocene, Benthic zone, Isotopes of carbon, chemistry.chemical_element, Submarine pipeline, Structural basin, Oxygen, Geology

Published

2018

13. Foraminiferal signatures of mass transport from the North-West Continental Shelf off Western Australia, IODP Expedition 356

Author

Craig S. Fulthorpe, Cecilia M. G. McHugh, Kara Bogus, Willem Renema, Briony Mamo, and Stephen J. Gallagher

Subjects

Mass transport, Throughflow, geography, Oceanography, geography.geographical_feature_category, North west, Continental shelf, Paleoceanography, Biogeosciences, Geology

Abstract

In 2015, Integrated Ocean Discovery Program Expedition 356 drilled along the margin off Western Australian to investigate the history of the Indonesian Throughflow (ITF) and its integral role in th...

Published

2018

14. Factors Contributing to the 2005-Present, Rapid Rise in Lake Levels, Dominican Republic and Haiti (Hispaniola)

Author

Cecilia M. G. McHugh, Paul Mann, Matthew J. Hornbach, and Vanshan Wright

Subjects

Hydrology, geography, geography.geographical_feature_category, Hydraulic conductivity, Groundwater flow, Flood myth, Threatened species, Drainage basin, Precipitation, Active fault, Geology, Water level

Abstract

Lakes Enriquillo and Azuei, the two largest lakes in Hispaniola and in the Caribbean, have risen 10 and 5 m respectively within the last 8 years. Higher lake levels have submerged towns, road systems, agricultural lands and utilities, and have threatened to submerge the major overland highway that connects the Dominican Republic and Haiti. In this study, we use CHIRP seismic data, satellite imagery, and regional meteorological data to quantify and assess controls on the recent lake level rises. Although data are limited, the analyses indicate that the lakes’ water level changes may be attributed to a combination of increased rainfall and natural or man-made changes to the hydraulic connectivity of the various water bodies within the drainage basin. We show that a weak correlation exists between changes in Lake Enriquillo’s and Azuei’s water levels and precipitation rates (0.2 and 0.08 respectively, 1984-2012) and that both lakes experience periods of anti-correlation where, for example, water level drops at Lake Azuei (~20 masl) coincide with water level rises at Lake Enriquillo (41 mbsl). From these observations, we propose that the lakes experience intermittent periods of hydraulic connectivity along reactivated or newly developed stratigraphic-controlled sub-surface transport pathways. We also note that moderately small earthquakes along the large active fault system that extends through both lakes may promote or limit hydraulic conductivity on decadal or shorter time scales. The extents to which recent earthquakes have triggered changes in groundwater flow at this site remain unclear but represent an important topic of future research.

Published

2015

15. Seafloor fault ruptures along the North Anatolia Fault in the Marmara Sea, Turkey: Link with the adjacent basin turbidite record

Author

Leonardo Seeber, M. Namık Çağatay, Marie-Helene Cormier, Nicole Braudy, Pierre Henry, Christopher C. Sorlien, and Cecilia M. G. McHugh

Subjects

geography, geography.geographical_feature_category, Turbidity current, Marine geology, North Anatolian Fault, Geology, Fault (geology), Structural basin, Oceanography, Seafloor spreading, Paleontology, Tectonics, Plate tectonics, Geochemistry and Petrology, Seismology

Abstract

The relation between seafloor fault ruptures and the generation of turbidity currents was investigated to better understand the structural growth of tectonic basins with direct implications for earthquake hazard assessment. This study focuses on the Holocene earthquake record of transtensional basins in the Marmara Sea, Turkey, that are associated with the North Anatolian Fault system. The physical and chemical composition of three 10 m-long cores recovered from the Central Basin was studied at high-resolution and turbidite–homogenite units were identified. Turbidite–homogenite units (T–H units) are complex deposits that consist of a sharp basal contact and multiple fining upward beds of sand to coarse silt, above. All are capped by a 25 cm to 75 cm thick layer of medium to fine silt. A chronology developed from radiocarbon and short-lived radioisotopes allowed the correlation of these T–H units to the historical record of earthquakes that in Turkey goes back 2000 years. We found that the best location to recover the most complete sedimentation record is in the deepest part of a basin or “depocenter” where T–H units constitute ~ 80% of the sediments. A very good correlation was established between T–H units in Central Basin and proximal inferred historic epicentres along the central Marmara segment of the North Anatolia Fault that occurred in 1343, 860, 740, and 557 AD, and two more distal earthquakes that occurred in 268 and 1963 (or possibly1964). These sedimentation events can then be referred to as “seismo-turbidites”. The results when compared to findings from other transform basins in Marmara Sea reveal a very good correlation between T–H units and historic ruptures. Most importantly, there is a strong correlation between the inferred locations of historical earthquakes and the preservation of turbidite–homogenite units in the basin adjacent to the inferred rupture. The 740 AD earthquake correlates with T–H units in Izmit Gulf and Central Basin and could represent a multi-segment rupture of the NAF. Generally, T–H units appear to be clustered through the Holocene sections, suggesting temporal earthquake clustering in the Marmara Sea region. Such clustering may account for the lack of T–H units and hence large ruptures through the Central Basin since 1343.

Published

2014

16. Submarine Paleoseismology Along Populated Transform Boundaries: The Enriquillo-Plantain-Garden Fault, Canal du Sud, Haiti, and the North Anatolian Fault, Marmara Sea, Turkey

Author

Cecilia M. G. McHugh, Leonardo Seeber, Matthew J. Hornbach, and Marie-Helene Cormier

Subjects

Canal du Sud, geography, submarine paleoseismology, geography.geographical_feature_category, historical earthquakes, North Anatolian Fault, Submarine, Transform fault, 2010 Haiti earthquake, Paleoseismology, Fault (geology), Oceanography, Turkey earthquakes, lcsh:Oceanography, Haiti earthquakes, lcsh:GC1-1581, Geology, Seismology, turbidites

Abstract

Continental transform boundaries cross heavily populated regions and are associated with destructive earthquakes worldwide. The devastating 1999 Turkey earthquakes and the offshore 2010 Haiti earthquake emphasized the urgent need to study the submerged segments of continental transforms. In response, the rapidly evolving field of submarine paleoseismology is focusing its attention on understanding the relationships between sedimentation, seafloor ruptures, and earthquake recurrence intervals along submarine faults. In Canal du Sud, Haiti, the 2010 earthquake-triggered sedimentation events were documented from nearshore to the deep basin by measuring the excess 234Th in sediment cores. This radioisotope, with a half-life of 24 days, tracked mass wasting, turbidites, turbidite-homogenite units, and a sediment plume that remained in the water column for at least two months after the earthquake. However, the turbidite units in Canal du Sud, Haiti, provide an incomplete record of the region's earthquake history, likely because sedimentation rates are too low for sedimentation events to be triggered by all earthquakes. In contrast, in the Marmara Sea basins, there is very good correlation between turbidites and the historical record of earthquakes dating back 2,000 years. The difference between these correlations is likely related to both sedimentation rates and particulars of the ruptures. Future research along the Enriquillo-Plantain-Garden fault in Haiti and along similar low sedimentation plate boundaries should focus on multiple fault segments in order to obtain complete earthquake recurrence histories.

Published

2014

17. Australian Summer Monsoon variability in the past 14,000 years revealed by IODP Expedition 356 sediments

Author

Cecilia M. G. McHugh, Stephen J. Gallagher, Yusuke Yokoyama, Lars Reuning, David De Vleeschouwer, and Takeshige Ishiwa

Subjects

Radiocarbon dating, Holocene climate variability, 010504 meteorology & atmospheric sciences, International Ocean Discovery Program Expedition 356, 010502 geochemistry & geophysics, Monsoon, 01 natural sciences, law.invention, Foraminifera, law, ddc:550, Holocene, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, biology, Terrigenous sediment, Continental shelf, Intertropical Convergence Zone, lcsh:QE1-996.5, lcsh:Geography. Anthropology. Recreation, biology.organism_classification, lcsh:Geology, Australian Summer Monsoon, Oceanography, lcsh:G, 13. Climate action, Interglacial, Northwestern Australia, General Earth and Planetary Sciences, Geology

Abstract

The International Ocean Discovery Program (IODP) Expedition 356 Site U1461 cored a Miocene to Holocene sedimentary sequence in the upper bathyal carbonate offshore northwestern Australia (NWA). The siliciclastic component of these strata is primarily derived from the Australian continent. Radiocarbon dating on macrofossils and planktonic foraminifera shows that the upper 14 m section at Site U1461 preserves Holocene sediments, recording regional climate variability. K/Ca ratios determined by X-ray fluorescence elemental analyses and %K determined by shipboard natural gamma ray analysis are interpreted as indicators of riverine run-off from the Australian continent. We document the consequences of the variability of the Australian Summer Monsoon (ASM) on the continental shelf of NWA. We report an increase in terrigenous input due to a riverine run-off after 11.5 ka, which reaches a maximum at similar to 8.5 ka. This maximum is the result of the enhanced ASM-derived precipitation in response to the southern migration of the Intertropical Convergence Zone (ITCZ). A decrease in riverine run-off due to a weakening of precipitation in the NWA region after 8.5 ka was caused by the northern migration of the ITCZ. We conclude that the ITCZ reached its southernmost position at 8.5 ka and enhanced precipitation in the NWA region. This Holocene record shows that even during interglacial periods, monsoonal variability was primarily controlled by the position of the ITCZ.

Published

2019

18. Offshore sedimentary effects of the 12 January 2010 Haiti earthquake

Author

Sean P. S. Gulick, N. Dieudonne, Marie-Helene Cormier, Katherine Ryan Mishkin, Steeve Symithe, John Templeton, Christopher C. Sorlien, Cecilia M. G. McHugh, Nicole Braudy, H. E. Johnson, M. B. Davis, Michael S. Steckler, Matthew J. Hornbach, Leonardo Seeber, Roby Douilly, and John B. Diebold

Subjects

Tectonics, geography, Turbidity current, Seiche, geography.geographical_feature_category, Transform fault, Geology, Sedimentary rock, Paleoseismology, Seismic risk, Fault (geology), Seismology

Abstract

Although the 12 January 2010 Haiti earthquake was one of the deadliest earthquakes in history, it left no clear geological evidence of rupture on land. As a tectonic event, the earthquake was complex; even the faults involved remain unclear. Using geophysical and coring data, we document direct evidence of the sedimentation generated by the catastrophic 12 January 2010 earthquake offshore. These studies document submarine paleoseismology methods that can be used for assessing seismic risk in this and other tectonic settings such as the California San Andreas fault, where deeper buried blind thrusts may exist. Shaking by the 12 January main shock triggered sediment failures and turbidity currents from coastal sources to deep-water sinks. An ~0.05 km 3 turbidite was deposited in the Canal du Sud basin (1750 m water depth) over 50 km 2 . Almost 2 months after the main shock, a 600-m-thick sediment plume was still present in the lowermost water column at this location. The turbidite was time correlated to the 12 January earthquake by the excess 234 Th in the sediments. With a half-life of 24 days, its presence documents an infl ux of terrigenous sediment mixing with marine sources derived from the basin slopes. This turbidite, and older ones observed beneath it, displays complex cross-bedded and fi ning-upward stratigraphy indicative of long waves and seiche oscillations that are consistent with locally reported tsunamis. This 12 January sedimentary record highlights the potential for submarine paleoseismology to unravel the seismic history of continental transform boundaries such as the Enriquillo‐Plantain Garden fault in the Dominican Republic, Haiti, and Jamaica, as well as other tectonic settings where no clear land-based evidence for a rupture exists.

Published

2011

19. High tsunami frequency as a result of combined strike-slip faulting and coastal landslides

Author

Sean P. S. Gulick, Katherine Ryan-Mishkin, Steeve Symithe, Richard W. Briggs, Marie-Helene Cormier, Clifford A Frohlich, Leonardo Seeber, John Templeton, H. E. Johnson, N. Dieudonne, Paul Mann, Frederick W. Taylor, Nicole Braudy, John B. Diebold, Matthew J. Hornbach, Roby Douilly, Christopher C. Sorlien, Cecilia M. G. McHugh, M. B. Davis, Michael S. Steckler, and Carol S. Prentice

Subjects

geography, geography.geographical_feature_category, Landslide, Fault (geology), Sedimentation, Field survey, Strike-slip tectonics, Slope failure, Erosion, General Earth and Planetary Sciences, Tsunami earthquake, Geomorphology, Seismology, Geology

Abstract

The 12 January 2010 Mw 7.0 Haiti earthquake exhibited primarily strike-slip motion but unusually generated a tsunami. An extensive field survey reveals that coastal strike-slip fault systems produce relief conducive to rapid sedimentation, erosion and slope failure, so that even modest predominantly strike-slip earthquakes can cause potentially catastrophic slide-generated tsunamis.

Published

2010

20. Geomorphic evidence for tilting at a continental transform: The Karamursel Basin along the North Anatolian Fault, Turkey

Author

M. H. Cormier, Alessandro Sorichetta, Leonardo Seeber, Andrea Taramelli, and Cecilia M. G. McHugh

Subjects

Graben, Half-graben, Transform fault, North Anatolian Fault, Slip (materials science), Structural basin, Fault scarp, Geomorphology, Holocene, Geology, Earth-Surface Processes

Abstract

Continental transform boundaries are characterised by regional transcurrent faults that locally slip obliquely and spawn rapidly subsiding and tilting basins. A type example is the North Anatolian Fault (NAF) that accounts for the westward motion of the Anatolian “platelet” relative to Asia at about 25 mm/yr. Many of the basins along the NAF are asymmetric half grabens that border a strand of the NAF on the extensional side of a fault bend and tilt obliquely toward the fault. A prominent example is the 17 km-long Karamursel half graben south of the NAF in Izmit Gulf, one of the starved basins flooded by the Marmara Sea. A tilt rate of 3°/10 kyr has been proposed for the submerged part of the basin within 2 km south of the NAF, on the basis of a tilted early Holocene paleo-shoreline. Very rapid tilt and subsidence have been reported for similar basins along the NAF, but the locus of tilt shifts relative to the basin and is short lived at any one place. We find evidence of recent tilting from surface flow patterns on the steep flank of the basin above the southern coastline, up to 6–8 km from the NAF. Drainage divides between 13 rivers mark a northward 8–10° tilted sub-planar surface that extrapolates down into the basement below the progressively tilted sediments of the basin. River profiles are only slightly concave below this surface. We interpret this as the bevelled surface that preceded tilting, and the immature comb-like drainage to be symptomatic of recent tilt. On the north flank of the basin, the drainage is equally steep but markedly different. It suggests a backward eroding fault scarp. Northward drainage into the Black Sea suggests a subtle but regional northward tilt of the Kocaeli Plateau, possibly a flexural response to unloading along the fault. Along the western NAF, rapid progressive tilting of sediments is typical of submarine transform basins. They provide ground truth for investigating the geomorphic effects of rapid tilting on land.

Published

2010

21. The last reconnection of the Marmara Sea (Turkey) to the World Ocean: A paleoceanographic and paleoclimatic perspective

Author

Yossi Mart, M. Namık Çağatay, Damayanti Gurung, Ummuhan Sancar, Lloyd H. Burckle, Cecilia M. G. McHugh, Liviu Giosan, and William B. F. Ryan

Subjects

Marine isotope stage, Shore, geography, geography.geographical_feature_category, Geology, Oceanography, law.invention, Mediterranean sea, Geochemistry and Petrology, law, Bathymetry, Younger Dryas, Glacial period, Radiocarbon dating, Sea level

Abstract

During the late glacial, marine isotope Stage 2, the Marmara Sea transformed into a brackish lake as global sea-level fell below the sill in the Dardanelles Strait. A record of the basin's reconnection to the global ocean is preserved in its sediments permitting the extraction of the paleoceanographic and paleoclimatic history of the region. The goal of this study is to develop a high-resolution record of the lacustrine to marine transition of Marmara Sea in order to reconstruct regional and global climatic events at a millennial scale. For this purpose, we mapped the paleoshorelines of Marmara Sea along the northern, eastern, and southern shelves at Cekmece, Prince Islands, and Imrali, using data from multibeam bathymetry, high-resolution subbottom profiling (chirp) and ten sediment cores. Detailed sedimentologic, biostratigraphic (foraminifers, mollusk, diatoms), X-ray fluorescence geochemical scanning, and oxygen and carbon stable isotope analyses correlated to a calibrated radiocarbon chronology provided evidence for cold and dry conditions prior to 15 ka BP, warm conditions of the Bolling-Allerod from ∼ 15 to 13 ka BP, a rapid marine incursion at 12 ka BP, still stand of Marmara Sea and sediment reworking of the paleoshorelines during the Younger Dryas at ∼ 11.5 to 10.5 ka BP, and development of strong stratification and influx of nutrients as Black Sea waters spilled into Marmara Sea at 9.2 ka BP. Stable environmental conditions developed in Marmara Sea after 6.0 ka BP as sea-level reached its present shoreline and the basin floors filled with sediments achieving their present configuration.

Published

2008

22. Regional patterns and local variations of sediment distribution in the Hudson River Estuary

Author

C. Bertinado, Frank O. Nitsche, William B. F. Ryan, Angela L. Slagle, Roger D. Flood, Suzanne M. Carbotte, Timothy C. Kenna, Robin E. Bell, and Cecilia M. G. McHugh

Subjects

Hydrology, geography, geography.geographical_feature_category, Sediment, Fluvial, Estuary, Aquatic Science, Oceanography, Deposition (geology), Tributary, Erosion, Sedimentary budget, Channel (geography), Geology

Abstract

The Hudson River Benthic Mapping Project, funded by the New York State Department of Environmental Conservation, resulted in a comprehensive data set consisting of high-resolution multibeam bathymetry, sidescan sonar, and sub-bottom data, as well as over 400 sediment cores and 600 grab samples. This detailed data set made it possible to study the regional pattern and the local variations of the sediment distribution in the Hudson River Estuary. Based on these data we describe the distribution of sediment texture and process-related sedimentary environments for the whole 240-km long estuary together with along-river variations of depth, cross-sectional area, and grain size distribution. We compare these parameters with changes in surrounding geology and tributary input and, as a result, divide the Hudson River Estuary in eight sections with distinct combinations of channel morphology, bedrock type, sediment texture, and sediment dynamics. The regional sediment distribution consists of marine sand-dominated sediments near the ocean end of the estuary, a large, mud-dominated central section, and fluvial sand-dominated sediments in the freshwater section of the Hudson River Estuary. This regional trend is highly modified by small-scale variations in the sediment distribution. These local variations are controlled by changes in morphology, bedrock, and tributary input, as well as by anthropogenic modifications of the estuary. In some areas these local variations are larger than the overall trend in sediment distribution and control the actual sediment type, as well as the condition of erosion and deposition in the estuary.

Published

2007

23. Submarine earthquake geology along the North Anatolia Fault in the Marmara Sea, Turkey: A model for transform basin sedimentation

Author

Jessica Dutton, Marie-Helene Cormier, Naci Gorur, Namik Cagatay, Alina Polonia, Leonardo Seeber, William B. F. Ryan, and Cecilia M. G. McHugh

Subjects

Seismic gap, Seiche, Paleoseismology, Structural basin, Fault scarp, Tectonics, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Sedimentary rock, Seismology, Geology, Submarine earthquake

Abstract

The submerged portions of the North Anatolia Fault system beneath the Marmara Sea were studied with high-resolution multibeam bathymetry, subbottom profiling and sediment cores. The major objectives were to learn about the seismic and tectonic history of the fault from the stratigraphic record at a scale similar to paleoseismic studies on land and to develop tools for submarine earthquake geology that can be applied to fault-controlled basins in general. We focused on Holocene sediment in several Marmara Sea basins of different sizes. The approach was to test whether: (1) the depocenters of the larger basins contain a record of all historic Ms > 7 earthquakes within the Marmara Sea region; (2) the small transform basins record earthquakes that rupture through them; (3) vertical and strike-slip Holocene deformation can be quantified; and (4) the effects of an earthquake generally includes both primary structural features due to rupture of the sea floor, such as strata offset, scarps and tilting, as well as secondary effects due to shaking, such as mass-wasting and gravitational flows. We found evidence of earthquakes that we correlate with historic events in 181 AD, 740 AD, 1063 AD, 1343 AD, 1509 AD, 1766 AD, 1894 AD and 1912 AD. The geologic evidence is primarily from those basins adjacent to the rupture as inferred from historic data. This suggests that coseismic deformation of the sea floor along the rupture is a critical factor in the sedimentary record. We propose a qualitative sedimentation model that relates this coseismic deformation to mass-wasting of the slope, scour of the basin floor, seiche motions and homogenite deposition. Frequent earthquake activity sheds sediments from the flanks, contributes to the much thicker sediment on the basin floor and decreases the likelihood of sediment failures in response to normal marine gravity-driven processes. The surveying techniques and approaches used have therefore the potential of documenting earthquake ruptures of fault segments and to extend the earthquake record far before the known history, thus improving hazard evaluations and the fundamental understanding of earthquake process.

Published

2006

24. Estuarine processes and their stratigraphic record: paleosalinity and sedimentation changes in the Hudson Estuary (North America)

Author

Jean Lynch-Stieglitz, Suzanne M. Carbotte, Robin E. Bell, Nicholas Christie-Blick, Stephen F. Pekar, Miriam C. Jones, and Cecilia M. G. McHugh

Subjects

geography, geography.geographical_feature_category, Sediment, Geology, Estuary, Sedimentation, Oceanography, Sedimentary structures, Geochemistry and Petrology, Paleosalinity, Bivalve shell, Holocene, Isotope analysis

Abstract

Paleosalinity estimates and rates of sedimentation inferred from core samples from the Hudson estuary for the interval between 6.4 and 1.3 ka indicate a possible role for the estuarine turbidity maximum (ETM) in influencing patterns of estuarine sedimentation at centennial to millennial time scales. Currently in the estuary, sedimentation is localized via sediment trapping particularly in the vicinity of the ETM, 13–26 km upstream from Battery Park (FBP) at the southern tip of Manhattan, in water depths greater than 4 m, and on the western side of the estuary. Data presented in this paper are from cores located within the segment of the estuary 29–50 km FBP. Age constraints are provided by C-14 dating. Paleoenvironmental interpretations are based upon paleosalinity estimates, grain size variability, and sedimentary structures. Paleosalinity was inferred on the basis of foraminiferal biofacies analysis and a new method for estimating summertime paleosalinity using oxygen isotope measurements in bivalve shell material. The isotopic analysis of a narrow size fraction (1.0– 1.7 mm) representing summer growth of a single bivalve species (Gemma gemma) reduces the uncertainty related to annual changes in temperature. Data from f45 km FBP indicate a gradual decrease in summertime paleosalinity between 6.4 and 2.0 ka from 25–20x to 15–10x (the latter is similar to present-day values). These results are consistent with the conclusion of an earlier low-resolution study. Sedimentation rates are generally low and are similar to the rate of sea-level rise in the Hudson River. Lowest sedimentation rates are noted in short ( 2.3 to f1.3 ka). We hypothesize that the observed pattern in sediment accumulation relates to a location for the ETM some 20 km upstream of its present position at 3 ka. Downstream migration of the ETM since 3 ka is ascribed to shoaling of the estuary, effectively squeezing the marine saltwater wedge in the same direction, and off marginal flats into the channel. Such shoaling would have enhanced the role of waves in mixing marine and fresher surface water, and reduced the effect of the ETM in

Published

2004

25. Pleistocene chronology of continental margin sedimentation

Author

Hilary Clement Olson and Cecilia M. G. McHugh

Subjects

geography, geography.geographical_feature_category, Milankovitch cycles, Pleistocene, Continental shelf, Sediment, Geology, Last Glacial Maximum, Oceanography, Paleontology, Geochemistry and Petrology, Interglacial, Glacial period, Ice sheet

Abstract

Commonly accepted models for the evolution of continental margins link sediment erosion, transport and deposition to eustasy. To test these models, we constructed an oxygen isotope record from 520 m of Pleistocene sediment recovered by the Ocean Drilling Program Leg 174A from the New Jersey continental slope. The N 18 O record was calibrated to SPECMAP oxygen isotope time scale [Imbrie et al. (1984), in: Berger et al. (Eds.), Milankovitch and Climate, 269^305] with radiocarbon ages, nannoplankton biostratigraphy, magnetostratigraphy, and opal and calcium carbonate stratigraphy. Sixteen glacial/interglacial fluctuations of global ice volume have been recorded in the Pleistocene: oxygen isotope stages (OIS) 1 (partial), 2^4, 5 (partial) and 8 throughout 18. Contrary to predicted sedimentation models, a classification of mass-wasting deposits, based on variations in the styles of soft-sediment deformation and grain size, shows that: (1) mass-wasting is not restricted to glacial times but is present during both glacial and interglacial stages; (2) glacial stages are dominated by fine-grained sediments some of which were deposited by gravity flows; and (3) the transitions from glacial to interglacial stages are characterized by the deposition of coarse sands. The sedimentary record shows large-scale trends that do not fit the traditional models of higher glacial sedimentation rates since there is no consistent variation in sediment accumulation between glacial and interglacial stages. Instead there are longer-term sedimentation patterns. Uniform sedimentation rates of 62 cm/kyr characterize the early middle Pleistocene (OIS 12^18), followed by varying rates from low to very high for three consecutive time periods: OIS 11 to 9 (98^560 cm/kyr), OIS 8 (52^560 cm/kyr), and OIS 5 to 2 (37^353 cm/kyr). Each of these depositional units is contained within one seismic-stratigraphic sequence and bounded by sequence boundaries. Their deposition was influenced by the supply of sediment rather than eustasy. Sediment supply was modulated by: (1) the transition from the dominance of obliquity to that of eccentricity (OIS 18^12 to OIS 11^1); and (2) the proximity of the ice sheet (located V150 km away from the paleoshoreline during the last glacial maximum). B 2002 Elsevier Science B.V. All rights reserved.

Published

2002

26. Cenozoic mass-transport facies and their correlation with relative sea-level change, New Jersey continental margin

Author

Gregory S. Mountain, Cecilia M. G. McHugh, and John E. Damuth

Subjects

Canyon, geography, geography.geographical_feature_category, Continental shelf, Geology, Mass wasting, Oceanography, Neogene, Sedimentary depositional environment, Paleontology, Continental margin, Geochemistry and Petrology, Facies, Progradation

Abstract

Mass-transport deposits reveal something of the timing, source areas and depositional processes that contributed to the evolution of the New Jersey continental margin. Many of the mass-transport deposits rest upon prominent stratal surfaces and sequence boundaries permitting evaluation of the relationship between mass wasting and eustatic change. Five distinct mass-transport facies representative of intercanyon regions of the slope, canyons and continental rise settings are recognized in the Ocean Drilling Program Leg 150 Sites (902–906). These mass-transport deposits consist predominantly of muddy slumps and debris flows, and to a lesser extent sandy mass flows and gravity-related flows. The styles of soft-sediment deformation, mineralogy, and biostratigraphy of these mass-transport deposits provide new information on the mass-wasting history of the continental margin. At intercanyon sites beneath the continental slope (Sites 902–904), mud with disseminated sand occurs mainly at sequence boundaries and related stratal surfaces in upper Oligocene to upper Miocene sections. In contrast, muddy and sandy debris flows and slumps occur at sequence boundaries, stratal surfaces and within sequences in upper Miocene through Pleistocene sections. The type and preservation of mass-transport facies (10–15% of the total sediment recovered) on the continental slope through time, is associated with changes in sediment progradation during the Miocene, which led to a change in the morphology and gradient of the slope throughout the late Neogene. Mass-wasting facies are best preserved (36% of the total sediment) in the canyon-fill deposits recovered from Site 906. The fill of modern Berkeley Canyon is composed of debris flows, whereas the fill of a buried middle Miocene canyon consists of clast supported slumps, debris flows, and turbidites, which document an early episode of canyon excavation and infilling. Apparently the middle Miocene canyon cutting event occurred very rapidly (∼2.5 Ma) and can be correlated to a prominent glacioeustatic sea-level lowering event (13.5±0.5 Ma). Approximately 30 m of debris flows and slumps accumulated at Site 905 on the continental rise during the middle Miocene. Lithologies and benthic foraminifer assemblages show that this material was derived from the continental slope. Downslope transport was again significant during the early Pleistocene at Site 905 when 215 m of slumps and debris flows accumulated. The lithology and age of the clasts and matrix suggest that these deposits resulted from episodes of canyon excavation deep into the lithified rocks of the adjacent continental slope.

Published

2002

27. Ichnofabrics of a Pleistocene slope succession, New Jersey margin: relations to climate and sea-level dynamics

Author

Cecilia M. G. McHugh, Francine M.G. McCarthy, Hilary Clement Olson, Hannelore Krawinkel, Gregory S. Mountain, and Charles E. Savrda

Subjects

Turbidity current, biology, Paleontology, Oceanography, biology.organism_classification, Sedimentary depositional environment, Thalassinoides, Facies, Siliciclastic, Ichnofacies, Cruziana, Ecology, Evolution, Behavior and Systematics, Geology, Earth-Surface Processes, Marine transgression

Abstract

Trace fossil and sedimentologic data were collected at 10 cm intervals throughout a virtually continuous, ∼520 m-thick Upper Pleistocene siliciclastic succession recovered at ODP Site 1073 (New Jersey margin). These data were examined in the context of isotopic, seismic, and palynologic proxies to document depositional and ichnologic responses to Quaternary climate and sea-level dynamics in an upper slope setting. Two broad, texturally defined sedimentary facies assemblages are recognized. The clay-rich assemblage reflects relatively rapid deposition, in part from turbidity currents and suspended plumes, and appears to be linked to cooler, sea-level fall and lowstand phases. The sand-rich assemblage reflects overall slower sedimentation by offshelf spillover and periodic winnowing and erosion, under the influence of contour and other bottom currents, during warmer transgressive/highstand phases. Facies of the sand-rich assemblage (muds, sandy muds, muddy sands, and sands) are completely bioturbated and are characterized by high densities of biogenic structures, including distinct burrow forms. In contrast, the clay-rich assemblage includes facies that exhibit limited biogenic disruption (laminated clay/silty clay and graded silt- or fine sand-to-clay couplets) and, on the whole, is characterized by lower densities of biogenic structures, most of which are diffuse burrow mottles. These ichnofabric trends reflect changes in ecological and taphonomic parameters (e.g. substrate stability and consistency, residence time of sediments in the benthic boundary layer, and degree of inter- and intrabed textural variability), many of which were governed by variations in sedimentation rate as mediated by glacio-eustacy. Recurring, identifiable ichnofossils are most common in facies of the sand-rich assemblage in the upper half of the Pleistocene succession. Finer-grained components of this assemblage (e.g. muds and sandy muds), representing quieter phases of highstand deposition, are characterized by a low-diversity distal Cruziana ichnofacies assemblage dominated by Schaubcylindrichnus and Phycosiphon (=Anconichnus), both of which represent the work of deposit-feeding worms. Narrow facies transitions that correspond to phases of rapid transgression are marked by occurrences of Thalassinoides. These crustacean burrow systems were excavated in coarser-grained, higher-energy facies (sands and muddy sands) and in closely associated firmground substrates produced by exhumation of consolidated muds by bottom currents and/or mass-wasting processes. The association of firmground ichnofabrics with marine flooding events in an upper slope setting demonstrates that the sequence stratigraphic utility of the Glossifungites ichnofacies extends beyond shelf depositional sequences to deeper-water deposits. The distribution of texturally defined facies and general ichnofabric parameters (e.g. degree of bioturbation) appears to respond to glacio-eustatic cycles through the entire Pleistocene record. However, the Schaubcylindrichnus–Phycosiphon assemblage and Thalassinoides are rare or absent altogether in the lower half of the succession, indicating that biological responses to, and the ichnologic record of, climate and sea-level dynamics may be strongly dependent on margin physiographic and bathymetric evolution.

Published

2001

28. Sedimentary features associated with channel overbank flow: examples from the Monterey Fan

Author

William B. F. Ryan and Cecilia M. G. McHugh

Subjects

geography, Turbidity current, geography.geographical_feature_category, Sediment, Geology, Oceanography, Sedimentary depositional environment, Geochemistry and Petrology, Overbank, Sedimentary rock, Bathymetry, Levee, Geomorphology, Communication channel

Abstract

Overbank flow of turbidity currents sweeping through the entrenched Monterey Fan Channel has generated erosional and depositional features along the channel walls and across the adjacent levees. These features, investigated with side-scan sonar, SeaBeam bathymetry, submersibles, and a towed camera sled include fields of sediment waves, overbank channels, gullied walls and terraces, and slump scars. Overbank flow occurs where the channel path is straight, but is accentuated along sharp outside bends. Along straight channel segments sediment waves trend oblique to the channel and are commonly present on the right-hand (when looking downstream) levee adjacent to the channel. Along curved segments of the channel path, large sediment waves, with crests sub-parallel to the channel and with wavelengths reaching 3 km, are present on the outside levee as far as 15 km from the channel. Commonly, a gully is present on the lee side of the sediment wave, near the mid-point of the wave crest. Gullies are the heads of a tributary system of overbank channels, which feed a larger trunk channel on the fan surface.

Published

2000

29. Widespread fluid expulsion on a translational continental margin: Mud volcanoes, fault zones, headless canyons, and organic-rich substrate in Monterey Bay, California

Author

Cecilia M. G. McHugh, Debra S. Stakes, H. Gary Greene, William B. F. Ryan, Daniel L. Orange, Jonathan B. Martin, James P. Barry, Norman Maher, and Don Reed

Subjects

Canyon, geography, geography.geographical_feature_category, Geochemistry, Geology, Authigenic, Cold seep, Diagenesis, Tectonics, Continental margin, Geomorphology, Bay, Mud volcano

Abstract

Remotely operated vehicle (ROV)-based mapping of tectonic features, zones of anomalous reflectivity, and geomorphic targets in Monterey Bay, California, demonstrates the regional abundance of fluid expulsion along the active transform margin between the Pacific and North American plates. Cold seeps—extant communities characterized by chemosynthetic bivalves, bacterial mats, and rare tubeworms—are the surface manifestations of present-day fluid expulsion of sulfide- and methane-rich fluids, whereas slabs, veins, and chimneys of authigenic carbonate represent regions of either dormant methane-rich fluid expulsion, or areas where the present rate of flow is too low to support chemosynthetic fauna. We have found both active and dormant fluid seepage along fault zones, at the surface expression of mud volcanoes, on organic-rich or permeable substrate, and within headless canyons across a wide range of depths within Monterey Bay. The fluid egress at these sites may be driven by a combination of (1) pore-space reduction caused by rapid sedimentation and/or tectonic compaction related to residual Pacific–North America compression, and (2) increased buoyancy due to a decrease in pore-fluid density related to diagenesis and/or catagenesis at depth. Although provocative, the relationship between topographically driven aquifer discharge and sea-floor fluid expulsion remains speculative for Monterey Bay. The widespread distribution of fluid expulsion features controlled by a variety of conduits in Monterey Bay implies that cold seeps may be common features on translational margins.

Published

1999

30. Upper Eocene ejecta of the New Jersey continental margin reveal dynamics of Chesapeake Bay impact

Author

Cecilia M. G. McHugh, Scott W. Snyder, and Kenneth G. Miller

Subjects

Tektite, Deposition (geology), Strewn field, Paleontology, Geophysics, Oceanography, Impact crater, Continental margin, Space and Planetary Science, Geochemistry and Petrology, Breccia, Earth and Planetary Sciences (miscellaneous), Sedimentary rock, Ejecta, Geology

Abstract

Evidence for the Chesapeake Bay Crater as the source for New Jersey continental margin ejecta is provided by fine-grained tektites and coarse-grained unmelted ejecta. The Upper Eocene ejecta deposit, now demonstrated to be part of the North American strewn field, occurs on the New Jersey continental margin at Ocean Drilling Program (ODP) Sites 904 and 903. The mineralogy, major oxide composition of the ejecta materials, and biostratigraphic age of the enclosing sediments link the origin of these ejecta to the recently recognized Chesapeake Bay impact crater, located only 330 km away. Sediments associated with the ejecta provide information about the dynamics of impact events. The 35-cm-thick ejecta-bearing layer can be subdivided into three subunits that indicate a sequence of events. Bottom subunit III documents sediment failure and deposition of gravel-sized fragments, middle subunit II records deposition of abundant sand-sized ejecta by gravity settling, and upper subunit I contains a 12-cm-thick sedimentary deposit containing rare silt-sized tektites and evidence of waning currents. These events are interpreted by linking sediment deposition to seismic ground motion and subsequent tsunami waves triggered by both the Chesapeake Bay impact and slope failures.

Published

1998

31. The influence of the San Gregorio fault on the morphology of Monterey Canyon

Author

William B. F. Ryan, Cecilia M. G. McHugh, Stephen L. Eittreim, and Donald L. Reed

Subjects

Canyon, geography, geography.geographical_feature_category, Monterey Canyon, Outcrop, Geology, Mass wasting, Fault (geology), Oceanography, Fault scarp, Lineation, Shear (geology), Geochemistry and Petrology, Geomorphology

Abstract

A side-scan sonar survey was conducted of Monterey Canyon and the San Gregorio fault zone, off shore of Monterey Bay. The acoustic character and morphology of the sonar images, enhanced by SeaBeam bathymetry, show the path of the San Gregorio fault zone across the shelf, upper slope, and Monterey Canyon. High backscatter linear features a few kilometers long and 100 to 200 m wide delineate the sea-floor expression of the fault zone on the shelf. Previous studies have shown that brachiopod pavements and carbonate crusts are the source of the lineations backscatter. In Monterey Canyon, the fault zone occurs where the path of the canyon makes a sharp bend from WNW to SSW (1800 m). Here, the fault is marked by NW–SE-trending, high reflectivity lineations that cross the canyon floor between 1850 m and 1900 m. The lineations can be traced to ridges on the northwestern canyon wall where they have ∼15 m of relief. Above the low-relief ridges, bowl-shaped features have been excavated on the canyon wall contributing to the widening of the canyon. We suggest that shear along the San Gregorio fault has led to the formation of the low-relief ridges near the canyon wall and that carbonate crusts, as along the shelf, may be the source of the high backscatter features on the canyon floor. The path of the fault zone across the upper slope is marked by elongated tributary canyons with high backscatter floors and `U'-shaped cross-sectional profiles. Linear features and stepped scarps suggestive of recent crustal movement and mass-wasting, occur on the walls and floors of these canyons. Three magnitude-4 earthquakes have occurred within the last 30 years in the vicinity of the canyons that may have contributed to the observed features. As shown by others, motion along the fault zone has juxtaposed diverse lithologies that outcrop on the canyon walls. Gully morphology and the canyon's drainage patterns have been influenced by the substrate into which the gullies have formed.

Published

1998

32. Upper Eocene tektite and impact ejecta layer on the continental slope off New Jersey

Author

Joel D. Blum, Cecilia M. G. McHugh, Christian Koeberl, and Billy P. Glass

Subjects

biology, Tektite, Geochemistry, biology.organism_classification, Deep sea, Strewn field, Foraminifera, Geophysics, Space and Planetary Science, Clastic rock, Planar deformation features, Shocked quartz, Ejecta, Geology

Abstract

— During Leg 150 of the Ocean Drilling Project (ODP), two sites (903C and 904A) were cored that have sediments of the same biostratigraphic age as the upper Eocene tektite-bearing ejecta layer at Deep Sea Drilling Project (DSDP) Site 612. Core 45X from ODP Site 904A (∼4 km north of Site 612) contains a 5 cm thick tektite-bearing ejecta layer, and Core 56 from Site 903C (∼8 km north-northwest of Site 904) contains a 2 cm thick layer of impact ejecta without any tektite or impact glass. Shocked quartz and feldspar grains, with multiple sets of planar deformation features (PDFs), and abundant coesite-bearing grains are present at both sites. The major oxide contents, trace element compositions, and rare earth element (REE) patterns of the Site 904 tektites are similar to those of the Site 612 tektites and to North American tektites (especially bediasites). The ɛSr and ɛNd values for one composite tektite sample from Site 904 fall within the range previously obtained for the Site 612 tektites, which defines a linear trend that, if extrapolated, would intersect the values obtained for North American tektites. The water contents of eight tektite fragments from Site 904 range from 0.017 to 0.098 wt%, and, thus, are somewhat higher than is typical for tektites. The heavy mineral assemblages of the 63–125 μm size fractions from the ejecta layers at Sites 612, 903, and 904 are all similar. Therefore, we conclude that the ejecta layer at all three sites is from the same impact event and that the tektites at Sites 904 and 612 belong to the North American tektite strewn field. Clinopyroxene-bearing (cpx) spherules occur below, or in the lower part of, the main ejecta layer at all three sites. At all three sites, the cpx spherules have been partly or completely replaced with pyrite that preserved the original crystalline textures. Site 612, 903, and 904 cpx spherules are similar to those found in the Caribbean Sea, Gulf of Mexico, central equatorial Pacific, western equatorial Pacific, and eastern Indian Ocean. The cpx event appears to have preceded the North American tektite event by 10–15 ka or less. The fining-upward sequence at all three sites and concentration of the denser, unmelted impact ejecta at the top of the tektite layer at Sites 612 and 904 suggest that the tektite-bearing ejecta layers are not the result of downslope redeposition and that the unmelted ejecta landed after the glass. Geographic variations in thickness of the tektite-bearing ejecta layer, the lack of carbonate clasts in the ejecta layer, and the low CaO content of the tektite glass suggest that the ejecta (including the tektite glass) were derived from the Chesapeake Bay structure rather than from the Toms Canyon structure. A sharp decline in microfossil abundances suggests that local environmental changes caused by the impact may have had adverse effects on benthic foraminifera, radiolaria, sponges, and fish as well as the planktic foraminifera.

Published

1998

33. New insights into geohazard risks in Jamaica, Haiti, and the Dominican Republic: A compendium of recent GeoscientistswithoutBorders results

Author

Lyndon Brown, Benjamin J. Phrampus, Renee McDonald, Austen Klausen, Joey Fontana, Emma Giddens, Cecilia M. G. McHugh, Gwen Carris, Brett Mattingly, Vanshan Wright, Connor Flynn, Zach Frone, Cliff Mauroner, Paul Mann, and Matthew J. Hornbach

Subjects

Slope failure, geography, geography.geographical_feature_category, Flooding (psychology), Active fault, Geohazard, Fault (geology), Port (computer networking), International airport, Archaeology, Seismology, Geology, Compendium

Abstract

Summary The Greater Antilles islands of Jamaica and Hispanola experience infrequent but devastating earthquakes. Currently, it remains unclear (1) where active faults extend into western Jamaica and the western Dominican Republic, (2) what the probability of large (>Mw 7) earthquakes is in these island, and (3) what citizens can do to better prepare for such events. To begin addressing these questions, an interdisciplinary team of students and researcher, funded by SEG’s Geoscientists without Borders, conducted a 10 day geophysical study in Jamaica and a 7 day geophysical study in Haiti and the Dominican Republic during the winter and spring of 2013. The Jamaica study included a detailed factor-of-safety analysis in Kingston Harbor, with particular emphasis on the Palisadoes sand spit and Port Royal that are home to the Norman Manley International Airport, and Jamaican Defense Force Coast Guard Headquarters, respectively. Our preliminary analysis indicates an Mw 5 earthquake at the western end of the Enriquillo-Plantain Garden fault could trigger slope failure in unconsolidated sediments near Port Royal, with a magnitude 7 event almost certainly capable of generating slope failures at this site. Ongoing analysis of sediment cores collected in Kingston Harbor provides insight into the timing and probability of slope failure. At the time of this submission, we are just preparing for our field campaign in Hispanola that analyzes the location and timing of earthquakes in central part of the island and possible hydrogeologic links to lake flooding in the region. We will provide preliminary result from our Hispanola study at the 2013 SEG annual meeting.

Published

2013

34. A Channeled Shelf Fan Initiated by Flooding of the Black Sea

Author

Yossi Mart, M. Namık Çağatay, Cecilia M. G. McHugh, Dina Vachtman, and William B. F. Ryan

Subjects

geography, Provenance, geography.geographical_feature_category, biology, biology.organism_classification, Inlet, Debris, Sedimentary depositional environment, Foraminifera, Paleontology, Oceanography, Sill, Glacial period, Pebble, Geology

Abstract

High-resolution mapping and reflection profiling reveal a depositional fan on the Black Sea SW shelf fed from the Strait of Istanbul (Bosporus). The fan is constructed with an initial deposit of pebbles mixed with glacial and post-glacial shell debris. The pebbles are identical in their composition to quartzite and gabbro recovered in drill cores from the Bosporus Strait. Directly above the pebble layer are mollusks and foraminifera of Mediterranean provenance dated at 6.9 ka bp (uncorrected). Synchronicity between the onset of fan construction and arrival of Mediterranean fauna suggests an origin linked to the connection of the Black Sea’s lake with the global ocean. The volume of the chaotic interior of the fan is comparable in magnitude to the volume excavated from the floor of the Bosporus Strait. We propose that when the exterior ocean breached the sill of this inlet, it transformed into an outburst of saltwater that gained energy as it enlarged the inlet. Torrents stripped the glacial and post-glacial covering from its pathway and scattered entrained debris in sheets and mounds as far away as the edge of the shelf. Even in areas where the pre-existing cover survived, its eroded surface attests to the passage of flooding water.

Published

2013

35. Biologic and geologic characteristics of cold seeps in Monterey Bay, California

Author

James P. Barry, H. Gary Greene, Cecilia M. G. McHugh, Daniel L. Orange, James Nybakken, C. H. Baxter, Donald L. R, Bruce H. Robison, and Randall E. Kochevar

Subjects

Chemosynthesis, education.field_of_study, biology, Monterey Canyon, Population, Aquatic Science, Oceanography, Beggiatoa, biology.organism_classification, Cold seep, Petroleum seep, Solemya, education, Bay, Geology

Abstract

Cold seep communities discovered at three previously unknown sites between 600 and 1000 m in Monterey Bay, California, are dominated by chemoautotrophic bacteria (Beggiatoa sp.) and vesicomyid clams (5 sp.). Other seep-associated fauna included galatheid crabs (Munidopsis sp.), vestimentiferan worms (Lamellibrachia barhami?), solemyid clams (Solemya sp.), columbellid snails (Mitrella permodesta, Amphissa sp.), and pyropeltid limpets (Pyropelta sp.). More than 50 species of regional (i.e. non-seep) benthic fauna were also observed at seeps. Ratios of stable carbon isotopes (δ13C) in clam tissues near ∼ 36‰ indicate sulfur-oxidizing chemosynthetic production, rather than non-seep food sources, as their principal trophic pathway. The “Mt Crushmore” cold seep site is located in a vertically faulted and fractured region of the Pliocene Purisima Formation along the walls of Monterey Canyon (∼ 635 m), where seepage appears to derive from sulfide-rich fluids within the Purisima Formation. The “Clam Field” cold seep site, also in Monterey Canyon (∼ 900 m) is located near outcrops in the hydrocarbon-bearing Monterey Formation. Chemosynthetic communities were also found at an accretionary-like prism on the continental slope near 1000 m depth (Clam Flat site). Fluid flow at the “Clam Flat” site is thought to represent dewatering of accretionary sediments by tectonic compression, or hydrocarbon formation at depth, or both. Sulfide levels in pore waters were low at Mt Crushmore (ca ∼ ∼ 0.2 mM), and high at the two deeper sites (ca 7.011.0 mM). Methane was not detected at the Mt Crushmore site, but ranged from 0.06 to 2.0 mM at the other sites.

Published

1996

36. Evidence for widespread creep on the flanks of the Sea of Marmara transform basin from marine geophysical data

Author

M. H. Cormier, S. Gürçay, Michael S. Steckler, O. Atgin, Cecilia M. G. McHugh, Donna J. Shillington, H. Kurt, Derman Dondurur, Günay Çifçi, D. Poyraz, John B. Diebold, Leonardo Seeber, Christopher C. Sorlien, Seda Okay, and Caner İmren

Subjects

Sedimentary depositional environment, Tectonics, Creep, Sediment, Bathymetry, Geology, Geophysics, Physical oceanography, Structural basin, Oceanography, Deposition (geology)

Abstract

"Wave" fields have long been recognized in marine sediments on the flanks of basins and oceans in both tectonically active and inactive environments. The origin of "waves" (hereafter called undulations) is controversial; competing models ascribe them to depositional processes, gravity-driven downslope creep or collapse, and/or tectonic shortening. Here we analyze pervasive undulation fields identified in swath bathymetry and new high-resolution multichannel seismic (MCS) reflection data from the Sea of Marmara, Turkey. Although they exhibit some of the classical features of sediment waves, the following distinctive characteristics exclude a purely depositional origin: (1) parallelism between the crests of the undulations and bathymetric contours over a wide range of orientations, (2) steep flanks of the undulations (up to similar to 40 degrees), and (3) increases in undulations amplitude with depth. We argue that the undulations are folds formed by gravity-driven downslope creep that have been augmented by depositional processes. These creep folds develop over long time periods (>= 0.5 m.y.) and stand in contrast to geologically instantaneous collapse. Stratigraphic growth on the upslope limbs indicates that deposition contributes to the formation and upslope migration of the folds. The temporal and spatial evolution of the creep folds is clearly related to rapid tilting in this tectonically active transform basin.

Published

2012

37. [Untitled]

Author

Peter Blum, David B. Kemp, Craig S. Fulthorpe, Kirsteen J. Tinto, Naomi Murakoshi, Itsuki Suto, Jaume Dinarès-Turell, Koichi Hoyanagi, Daniel A. Hepp, Takeshi Ohi, Maria-Christina Ciobanu, Laura Pea, Kathleen M. Marsaglia, George E. Claypool, Xuan Ding, Mathieu Richaud, Gregory H. Browne, Simon C. George, Gilles Guerin, Helen Lever, Young-Gyun Kim, Angela L. Slagle, John M. Jaeger, Shungo Kawagata, Martin P. Crundwell, Stacie A. Blair, Cecilia M. G. McHugh, Julius S. Lipp, Go-Ichiro Uramoto, Michelle A. Kominz, Toshihiro Yoshimura, Robert M Carter, and Susumu Tanabe

Subjects

Shore, Engineering, geography, geography.geographical_feature_category, Operations research, business.industry, Ocean current, Legacy system, Drilling, Plan (drawing), Earth system science, Engineering management, Agency (sociology), Geological survey, business

Abstract

[Extract - Foreword] The Integrated Ocean Drilling Program (IODP) is now in the latter half of its decadal program (2003–2013). As envisioned in the Initial Science Plan (ISP), IODP expeditions take advantage of three scientific ocean drilling platforms that enable us to cover unprecedented areas of wide oceans, from ice-covered shallow water to full ocean depths. Drilling miles of depth below seafloor, now part of IODP capabilities, is the major advance from the program predecessors, the Deep Sea Drilling Project and the Ocean Drilling Program. The living Earth is a dynamic system that is continuously evolving. IODP seeks to understand this complex and unique system through scientific ocean drilling, sampling, and experimenting in deep holes, along with advancement of related scientific disciplines. IODP is an international collaboration among scientists and nations with keen aspirations to attain the scientific goals of the ISP. IODP currently includes participating members from 24 nations. The Proceedings present the scientific and engineering results of IODP drilling projects, each designed to better understand the past, present, and future of the Earth system. IODP expeditions begin with scientists who submit research drilling proposals to test new and innovative ideas, then the proposals progress to international scientific advisors (Science Advisory Structure) who nurture, evaluate, rank, and prioritize proposals. Scientists also schedule the science operations, select science party members from scores of international scientists qualified to participate, plan platform operations, ready the drillship, and choose borehole locations. The science party, collectively and individually, conducts science on board and on shore. The co-chief scientists on each expedition are responsible for synthesizing the scientific results as hallmark of expedition. Ocean-drilling achievements help us to understand and interpret phenomena in various parts of the Earth system. Achievements in the two legacy drilling programs have validated the scientific concepts behind plate tectonics, contributed to the understanding of ocean circulation changes, and extended our knowledge of long- and short-term climate change. IODP is truly an expansion and extension of the scientific research conducted by the legacy programs, engaging in cutting-edge research concerning topics of global importance. IODP drilling platform operations are conducted by three Implementing Organizations (IOs). Riserless platform operations are conducted by the U.S. Implementing Organization (USIO), comprising the Consortium for Ocean Leadership, Inc., Texas A&M University through the Texas A&M Research Foundation, and Lamont-Doherty Earth Observatory of Columbia University. Riser platform operations are conducted by the Japan Agency for Marine-Earth Science and Technology through Japan's Center for Deep Earth Exploration in cooperation with the Center for Advanced Marine Core Research at Kochi University. Mission-specific platform operations are conducted by the European Consortium for Ocean Research Drilling (ECORD) Science Operator (ESO), comprising the British Geological Survey, Bremen University, and the European Petrophysics Consortium. The European IO currently represents the ocean-drilling efforts of 16 nations in Europe, plus Canada. The discoveries presented in this volume build upon layers of knowledge and science developed over roughly the last fifty years. Expedition Proceedings are published by IODP Management International for IODP under the sponsorship of the U.S. National Science Foundation (NSF), Japan's Ministry of Education, Culture, Sports, Science and Technology, and other IODP members. The material is based upon research supported under Contract OCE-0432224 from NSF.

Published

2011

38. [Untitled]

Author

Takeshi Ohi, Cecilia M. G. McHugh, Susumu Tanabe, Go-Ichiro Uramoto, Kirsteen J. Tinto, Naomi Murakoshi, Maria-Christina Ciobanu, Gregory H. Browne, Xuan Ding, Gilles Guerin, Peter Blum, John M. Jaeger, Angela L. Slagle, Toshihiro Yoshimura, Young-Gyun Kim, Craig S. Fulthorpe, Simon C. George, David B. Kemp, Jaume Dinarès-Turell, Itsuki Suto, Mathieu Richaud, Julius S. Lipp, Martin P. Crundwell, Laura Pea, Daniel A. Hepp, Helen Lever, Kathleen M. Marsaglia, Michelle A. Kominz, Shungo Kawagata, Stacie A. Blair, George E. Claypool, Koichi Hoyanagi, and Bob Carter

Subjects

Sedimentary depositional environment, Paleontology, geography, Oceanography, geography.geographical_feature_category, Continental margin, Terrigenous sediment, Continental shelf, Sequence stratigraphy, Sedimentary rock, Thermohaline circulation, Sea level, Geology

Abstract

Integrated Ocean Drilling Program (IODP) Expedition 317 was devoted to understanding the relative importance of global sea level (eustasy) versus local tectonic and sedimentary processes in controlling continental margin sedimentary cycles. The expedition recovered sediments from the Eocene to recent period, with a particular focus on the sequence stratigraphy of the late Miocene to recent, when global sea level change was dominated by glacioeustasy. Drilling in the Canterbury Basin, on the eastern margin of the South Island of New Zealand, takes advantage of high rates of Neogene sediment supply, which preserves a high-frequency (0.1–0.5 m.y.) record of depositional cyclicity. The Canterbury Basin provides an opportunity to study the complex interactions between processes responsible for the preserved stratigraphic record of sequences because of the proximity of an uplifting mountain chain, the Southern Alps, and strong ocean currents. Currents have locally built large, elongate sediment drifts within the prograding Neogene section. Expedition 317 did not drill into one of these elongate drifts, but currents are inferred to have strongly influenced deposition across the basin, including in locations lacking prominent mounded drifts. Upper Miocene to recent sedimentary sequences were cored in a transect of three sites on the continental shelf (landward to basinward, Sites U1353, U1354, and U1351) and one on the continental slope (Site U1352). The transect provides a stratigraphic record of depositional cycles across the shallow-water environment most directly affected by relative sea level change. Lithologic boundaries, provisionally correlative with seismic sequence boundaries, have been identified in cores from each site and provide insights into the origins of seismically resolvable sequences. This record will be used to estimate the timing and amplitude of global sea level change and to document the sedimentary processes that operate during sequence formation. Sites U1353 and U1354 provide significant, double-cored, high-recovery sections through the Holocene and late Quaternary for high-resolution study of recent glacial cycles in a continental shelf setting. Continental slope Site U1352 represents a complete section from modern slope terrigenous sediment to hard Eocene limestone, with all the associated lithologic, biostratigraphic, physical, geochemical, and microbiological transitions. The site also provides a record of ocean circulation and fronts during the last ~35 m.y. The early Oligocene (~30 Ma) Marshall Paraconformity was the deepest drilling target of Expedition 317 and is hypothesized to represent intensified current erosion or nondeposition associated with the initiation of thermohaline circulation following the separation of Australian and Antarctica. Expedition 317 set a number of scientific ocean drilling records: (1) deepest hole drilled in a single expedition and second deepest hole in the history of scientific ocean drilling (Hole U1352C, 1927 m); (2) deepest hole and second deepest hole drilled by the R/V JOIDES Resolution on a continental shelf (Hole U1351B, 1030 m; Hole U1353B, 614 m); (3) shallowest water depth for a site drilled by the JOIDES Resolution for scientific purposes (Site U1353, 84.7 m water depth); and (4) deepest sample taken by scientific ocean drilling for microbiological studies (1925 m, Site U1352). Expedition 317 supplements previous drilling of sedimentary sequences for sequence stratigraphic and sea level objectives, particularly drilling on the New Jersey margin (Ocean Drilling Program [ODP] Legs 150, 150X, 174A, and 174AX and IODP Expedition 313) and in the Bahamas (ODP Leg 166), but includes an expanded Pliocene section. Completion of at least one transect across a geographically and tectonically distinct siliciclastic margin was the necessary next step in deciphering continental margin stratigraphy. Expedition 317 also complements ODP Leg 181, which focused on drift development in more distal parts of the Eastern New Zealand Oceanic Sedimentary System (ENZOSS).

Published

2010

39. Contemporary sedimentary processes in the Monterey Canyon-fan system

Author

Cecilia M. G. McHugh, Barbara Hecker, and William B. F. Ryan

Subjects

Canyon, geography, geography.geographical_feature_category, Monterey Canyon, Continental shelf, Bedrock, Geology, Escarpment, Oceanography, Thalweg, Geochemistry and Petrology, Benthic zone, Sedimentary rock, Geomorphology

Abstract

A study of the Monterey Canyon and fan was conducted to investigate contemporary sedimentary activity using a camera sled, Alvin dives and Sea-Beam bathymetry. Physical characteristics and plan view morphology of the walls, terraces, thalweg floor and levees of the Monterey Canyon and fan, as well as the gullied and non-gullied regions of the adjacent continental slope have been studied. The canyon floor and fan valley thalweg channel from 2900 to 3500 m exhibited properties indicative of moderate to low energy conditions (weak currents, smoothed sea-bed, deposits of disintegrated kelp, bioturbated mud substrate, fecal pellets, absence of scour). Chemosynthetic communities consisting of clams and a pogonophoran, were found in the fan valley from 3000 to 3600 m. Local areas of rockfalls and slumps from the canyon and fan valley walls were not fresh (sedimented, abundantly colonized by benthic biota). Terraces and levee crests were mud-draped and bedrock exposures on canyon walls were encrusted by benthic organisms. Freshest disturbances were found in gullies on the adjacent continental slope where bedrock was scoured clean of sediment and loose debris. A major submarine slide detached from escarpments on the lower slope, and extends across the fan. The slide surface was mud-draped, hummocky, and contained bedforms with wavelengths up to 150 m and up to 10 m relief. The survey was conducted shortly before the Loma Prieta earthquake (October 17, 1989) that caused substantial ground motion in on-shore regions of Monterey Bay. Any substantial sub-sea disturbances generated by the ensuing earthquake should be discernable from the pre-earthquake state by comparison with the deep-sea photographs and observations.

Published

1992

40. The Long-Term Stratigraphic Record on Continental Margins

Author

David Goldberg, Craig S. Fulthorpe, Kenneth G. Miller, Heike Delius, Lincoln F. Pratson, Daniel L. Orange, Gregory S. Mountain, Michael S. Steckler, Donald H. Monteverde, Robert L. Burger, Cecilia M. G. McHugh, and J. A. Austin

Subjects

Paleontology, Continental margin, Geomorphology, Geology, Term (time)

Published

2009

41. δ13C, δ15N and δ18O of Calyptogena phaseoliformis (bivalve mollusc) from the Ascension Fan-Valley near Monterey, California

Author

Cecilia M. G. McHugh, Barbara Hecker, Robert W. Embley, Chris Harrold, Greg H. Rau, and C. H. Baxter

Subjects

δ13C, biology, δ18O, Calyptogena phaseoliformis, δ15N, Bivalvia, biology.organism_classification, Oceanography, Dietary nitrogen, Geography, Isotopes of carbon, General Earth and Planetary Sciences, Mollusca, General Environmental Science

Abstract

The δ13C and δ15N of the soft tissues of two Calyptogena phaseoliformis specimens sampled from the floor of Ascension Fan-Valley, off the Monterey Peninsula, California, ranged from -35.0 to -33.6% and -6.2 to -0.6%, respectively. The carbon isotope abundances are similar to those of other Calyptogena known or believed to be nutritionally dependent on sulfide-based chemoautotrophic symbionts. Calyptogena δ15N values and their geographic variation indicate an unusual source of dietary nitrogen for these animals. The δ13C and δ18O values for Calyptogena shells from the Ascension and Monterey Fan-Valleys approximate those reported for Calyptogena from three other locations in the Pacific and appear to reflect shell formation from constituents within ambient deep-ocean water.

Published

1990

42. Benthic Habitat Mapping in the Hudson River Estuary

Author

Cecilia M. G. McHugh, John W. Ladd, Roelof Versteeg, Henry J. Bokuniewicz, Robin E. Bell, M. H. Cormier, Suzanne M. Carbotte, Elizabeth A. Blair, William B. F. Ryan, Roger D. Flood, Vicki Lynn Ferrini, and Joanne Thissen

Subjects

Benthic habitat, Fishery, geography, Oceanography, geography.geographical_feature_category, Estuary, Geology

Published

2006

43. North Anatolian Fault in the Gulf of Izmit (Turkey): Rapid vertical motion in response to minor bends of a nonvertical continental transform

Author

Cecilia M. G. McHugh, Namik Cagatay, Leonardo Seeber, Marie-Helene Cormier, William B. F. Ryan, Luca Gasperini, Ömer Emre, Kori Newman, Giovanni Bortoluzzi, Alina Polonia, Naci Görür, and Enrico Bonatti

Subjects

Shore, Atmospheric Science, geography, geography.geographical_feature_category, Ecology, Lineament, Paleontology, Soil Science, North Anatolian Fault, Forestry, Aquatic Science, Fault (geology), Oceanography, Bathymetric chart, Seafloor spreading, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Fault block, Seismology, Geology, Earth-Surface Processes, Water Science and Technology, Mud volcano

Abstract

[1] The catastrophic rupture of the North Anatolian Fault east of the Marmara Sea on 17 August 1999 highlighted a need for mapping the underwater extension of that continental transform. A new bathymetric map of Izmit Gulf indicates that the fault follows the axis of the gulf with a few minor bends. Submerged shorelines and shelf breaks that formed during the Last Glacial Maximum provide markers to quantify vertical deformation. Variable tilting of these horizons reveals that vertical deformation is highest just south of the fault. A correlation between vertical deformation of the southern fault block and distance to fault bends can be accounted for by a fault dipping steeply to the south. Hence subsidence (uplift) of the southern, hanging wall block would be expected where the fault strikes at a slightly transtensional (transpressional) orientation to relative plate motion. Subsidence reaches about 8 mm/yr west of the town of Golcuk and might be accommodated in 1–2 m subsidence events during large earthquakes. That scenario is compatible with the tsunami runups and the coseismic subsidence of the southern shore that occurred in 1999. Seafloor morphology also suggests that earthquakes are accompanied by widespread gas and fluid release. The periphery of the deepest basin displays a hummocky texture diagnostic of sediment fluidization, and mud volcanoes occur west of Hersek peninsula that might be activated by earthquakes. Finally, the backscatter imagery reveals a series of lineaments midway through the gulf that are interpreted as products of the 1999 surface rupture. The seafloor is undisturbed farther west, suggesting that surface slip decreased to an insignificant level beyond Hersek. Possibly, the stress shadow from the 10 July 1894 earthquake, which was felt strongly along the western Izmit Gulf, contributed to arrest the 1999 surface rupture.

Published

2006

44. Integrative Acoustic Mapping Reveals Hudson River Sediment Processes and Habitats

Author

William B. F. Ryan, Steven N. Chillrud, R. Cerrato, David L. Strayer, Suzanne M. Carbotte, Roger D. Flood, Angela L. Slagle, Timothy C. Kenna, Robin E. Bell, Vicki Lynn Ferrini, Frank O. Nitsche, and Cecilia M. G. McHugh

Subjects

geography, geography.geographical_feature_category, Sediment, Estuary, Physical oceanography, Oceanography, Geophysics, Habitat, Benthic zone, Human settlement, General Earth and Planetary Sciences, Ecosystem, Sedimentary rock, Submarine geology, Geology

Abstract

Rivers and estuaries around the world are the focus of human settlements and activities. Needs for clean water, ecosystem preservation, commercial navigation, industrial development, and recreational access compete for the use of estuaries, and management of these resources requires a detailed understanding of estuarine morphology and sediment dynamics. This article presents an overview of the first estuary-wide study of a heavily used estuary the Hudson River, based on high-resolution acoustic mapping of the river bottom. The integration of three high-resolution acoustic methods with extensive sampling reveals an unexpected complexity of bottom features and allows detailed classification of the benthic environment in terms of riverbed morphology, sediment type, and sedimentary processes.

Published

2005

45. Uplift and subsidence from oblique slip: the Ganos-Marmara Bend of the North Anatolian Transform, western Turkey

Author

Namik Cagatay, Christopher C. Sorlien, Marie-Helene Cormier, Cecilia M. G. McHugh, Naşide Özer, Ömer Emre, Leonardo Seeber, and Alina Polonia

Subjects

Seismic gap, uplift, Transtension, Anticline, North Anatolian Fault, Transform fault, Slip (materials science), subsidence, Transpression, Geophysics, Thrust fault, Ganos–Marmara bend, Geology, Seismology, Earth-Surface Processes

Abstract

Bends that locally violate plate-motion-parallel geometry are common structural elements of continental transform faults. We relate the vertical component of crustal motion in the western Marmara Sea region to the NNW-pointing ∼18° bend on the northern branch of the North Anatolian Fault (NAF-N) between the Ganos segment, which ruptured in 1912, and the central Marmara segment, a seismic gap. Crustal shortening and uplift on the transpressive west side of the bend results in the Ganos Mountain; crustal extension and subsidence on the transtensional east side produce the Tekirdag Basin. We propose that this vertical component of deformation is controlled by oblique slip on the non-vertical north-dipping Ganos and Tekirdag segments of the North Anatolian Fault. We compare Holocene with Quaternary structure across the bend using new and recently published data and conclude the following. First, bend-related vertical motion is occurring primarily north of the NAF-N. This suggests that this bend is fixed to the Anatolian side of the fault. Second, current deformation is consistent with an antisymmetric pattern centered at the bend, up on the west and down on the east. Accumulated deformation is shifted to the east along the right-lateral NAF-N, however, leading to locally opposite vertical components of long- and short-term motion. Uplift has started as far west as the landward extension of the Saros trough. Current subsidence is most intense close to the bend and to the Ganos Mountain, while the basin deepens gradually from the bend eastward for 28 km along the fault. The pattern of deformation is time-transgressive if referenced to the material, but is stable if referenced to the bend. The lag between motion and structure implies a 1.1–1.4 Ma age for the basin at current dextral slip rate (2.0–2.5 cm/year). Third, the Tekirdag is an asymmetric basin progressively tilted down toward the NAF-N, which serves as the border fault. Progressive tilt suggests that the steep northward dip of the fault decreases with depth in a listric geometry at the scale of the upper crust and is consistent with reactivation of Paleogene suture-related thrust faults. Fourth, similar thrust-fault geometry west of the bend can account for the Ganos Mountain anticline/monocline as hanging-wall-block folding and back tilting. Oblique slip on a non-vertical master fault may accommodate transtension and transpression associated with other bends along the NAF and other continental transforms.

Published

2004

46. Holocene slip rate of the North Anatolian Fault beneath the Sea of Marmara

Author

Enrico Bonatti, Marie-Helene Cormier, Alessandro Amorosi, Lucilla Capotondi, Naci Görür, Luca Gasperini, Alina Polonia, Leonardo Seeber, Cecilia M. G. McHugh, Giovanni Bortoluzzi, Namik Cagatay, POLONIA A., GASPERINI L., AMOROSI A., BONATTI E., BORTOLUZZI G., CAGATAY N., CAPOTONDI L., CORMIER M.-H., GORUR N., MCHUGH C., and SEEBER L.

Subjects

Seismic gap, geography, geography.geographical_feature_category, North Anatolian Fault, Geodetic datum, Fault (geology), Structural basin, Geophysics, Seismic hazard, Gulf of Izmit, submarine earthquake geology, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), slip rate, Marmara Sea, Seismology, Holocene, Geology, Slip rate

Abstract

The North Anatolian Fault (NAF) is a major continental transform system that extends E-W across Turkey for over 1600 km, separating the Anatolian and Eurasian plates. A portion of its northern branch runs below the Sea of Marmara. This portion constitutes a "seismic gap" because the last destructive earthquakes occurred at the western (1912 Ganos earthquake, M 7.4) and eastern (1999 Izmit and Duzce earthquakes, M-w 7.4, 7.2) edges of the Marmara basin. It is likely that fault ruptures will fill this gap in the next decades. This region of the North Anatolian Fault is critical to our understanding of fault interactions, stress buildup during seismic cycle and seismic hazard in the Istanbul area. We obtained high-resolution acoustic images of the NAF in the floor of the eastern Marmara Sea (Gulf of Izmit), and measured fault-related offsets of C-14-dated subseafloor channels and paleoshorelines. The resulting average slip rate on the fault is similar to10 mm/year for the last 10 kyr. This is less than half the total Anatolia-Eurasia relative motion, estimated at 24 mm/year for the last similar to10 years from satellite geodetic measurements. We conclude that either much of the strike-slip motion along this branch of the NAF did not occur on the main fault segment or the slip rate increased recently, or both. These results affect kinematic models of the NAF and assessments of seismic hazard for the city of Istanbul and the surrounding region. (C) 2004 Elsevier B.V. All rights reserved.

Published

2004

47. Studying tectonic hazards along continental transform boundaries

Author

Cecilia M. G. McHugh and Leonardo Seeber

Subjects

Seismic gap, Tectonics, geography, geography.geographical_feature_category, Transtension, General Earth and Planetary Sciences, Drilling, Transform fault, Seismic risk, Fault (geology), Geology, Seismology

Abstract

Integrated Ocean Drilling Program Marmara-Trans Workshop; Istanbul, Turkey, 13–16 June 2011 Continental transform boundaries such as the North Anatolia Fault (NAF) in Turkey cross heavily populated regions and are associated with destructive earthquakes. Transtension along the northern branch of the NAF is responsible for the formation of the Marmara Sea, which is 150 kilometers long and subdivided into three approximately 1200-meter-deep subsiding basins. This submerged segment of the NAF is considered a seismic gap presenting high risk to Istanbul and its surroundings. To the east, two earthquakes in 1999 caused much damage and approximately 17,000 deaths.

Published

2011

48. The Role of Diagenesis in Exfoliation of Submarine Canyons

Author

Cecilia M. G. McHugh, William B. F. Ryan, and B. Charlotte Schreiber

Subjects

Canyon, geography, geography.geographical_feature_category, Bedding, Bedrock, Geochemistry, Energy Engineering and Power Technology, Geology, Submarine canyon, Diagenesis, Paleontology, Fuel Technology, Continental margin, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Siliciclastic, Sedimentary rock

Abstract

On the lower slope of the U.S. continental margin offshore New Jersey, submarine canyons incise carbonate sediments, and the canyon morphology is characterized by steep, nearly vertical walls, linear and flat canyon floors, stepped terraces, "U"-shaped cross-sectional profiles, and the lack of well-developed tributary gullies. Canyon morphology contrasts sharply with that of canyons in the upper and middle slope that are cut into siliciclastic sediments and have "V"-shaped profiles, narrow sinuous thalwegs, and dendritic tributary gullies. A research program was undertaken to study the role that diagenesis and the physical properties of bedrock have in formation and growth of submarine canyons in a carbonate setting. Alvin dives were conducted on the New Jersey lower slope where canyons incise siliceous chalks or chalk rocks and siliceous porcellanitic chalks. Morphological canyon components such as steep walls, flat floors and terraces, linear chutes, and joint surfaces were observed and sampled. Volume reduction resulting from fluid expulsion due to the opal-A to opal-CT diagenetic transformation, which occurs with progressive burial of the silica-rich chalks, contributes greatly to fracturing of the bedrock. Fracturing at all scales is oriented subparallel and vertical to bedding in the porcellanites, and vertical in the chalk rocks. Unroofing of overburden and canyon excavation by mass-wasting causes exfoliation and diagenetically generated fractures to expand. Once canyon formation begins, it continues development by positive feedback since there is a continued stress-release fracturing: loss of support leads to failure, and erosion continues by spalling and sliding of blocks from the extensively fractured rocks. Results obtained in this study provide a timing for fracture formation in deep-sea, silica-rich chalks. Visual observations and sampling provide an understanding of fracture orientation, scale, and network communication. Observations of modern sedimentary processes in a canyon/slope carbonate setting help to understand ancient environments.

Published

1993

49. Rapid subsidence and sedimentation from oblique slip near a bend on the North Anatolian transform fault in the Marmara Sea, Turkey

Author

Alina Polonia, Marie-Helene Cormier, Christopher C. Sorlien, Leonardo Seeber, Ömer Emre, and Cecilia M. G. McHugh

Subjects

Strain partitioning, Oblique case, North Anatolian Fault, Transform fault, Geology, Slip (materials science), Structural basin, Quaternary, Seismology, Turbidite

Abstract

Several basins are developing near bends on strands of the North Anatolian transform fault in northwest Turkey. Oblique slip on these faults, rather than strain partitioning, accounts for trans- tension and subsidence. These basins are asymmetric, and tilt and subside most rapidly at their narrow ends near the bends. The turbidite surface marking the floor of the Cinarcik Basin (eastern Marmara Sea) was mostly abandoned at a sudden drop in sedi- mentation, which was likely coincident with the 14 ka lake-sea transition, and is now a warped reference surface from which we can measure strain and sedimentation. Subsidence and tilt are rap- id, but do not require late Quaternary changes in regime. They are linked to transcurrent motion by slip parallel to an oblique bend on the North Anatolian fault and suggest tsunamogenic ver- tical motion in large Marmara Sea earthquakes.

Published

2006

50. Observations in Monterey Canyon and Fan Valley using the submersible Alvin and a photographic sled

Author

William R. Normark, Stephen L. Eittreim, William B. F. Ryan, Robert W. Embley, H. Gary Greene, and Cecilia M. G. McHugh

Subjects

Oceanography, Monterey Canyon, Geology

Published

1989