South Atlantic Cenozoic Paleoceanography

Hsü, Kenneth J.; McKenzie, Judith; Oberhänsli, Hedi; Weissert, Helmut; Wright, R.C.

doi:10.2973/dsdp.proc.73.138.1984

Cited by 5 publications

(4 citation statements)

References 21 publications

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“…Since then, most reconstructions of the CCD have shown a clear shoaling trend from the Oligocene into the Miocene (e.g., van Andel, 1975;Heath et al, 1977;Hsu et al, 1984;Rea and Leinen, 1985), a trend similar to the one seen here. The study by Rea and Leinen (1985) of nearequatorial South Pacific sites is of particular interest, however, because of their observations of carbonate accumulation above the CCD.…”

Section: Discussionsupporting

confidence: 74%

“…The principal paleoceanographic objective of Leg 115 was to use this new technology to recover a depth transect of continuously cored sedimentary sequences from the tropical Indian Ocean that would allow reconstruction of the dynamic features of the regional carbonate system through the late Cenozoic. Deep-sea drilling has long since established that dissolution levels in the different ocean basins have fluctuated markedly during the Cenozoic (e.g., Berger and Winterer, 1974;van Andel, 1975;Heath et al, 1977;Hsu et al, 1984;Rea and Leinen, 1985). In general, these studies have shown that long-term changes in the patterns of carbonate distribution have been similar between the major ocean basins, suggesting a global forcing mechanism perhaps linked to changing sea level or to a changing supply of carbonate to the oceans (Kennett, 1982).…”

Section: Introductionmentioning

confidence: 99%

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Late Cenozoic Carbonate Accumulation and the History of the Carbonate Compensation Depth in the Western Equatorial Indian Ocean

Peterson¹,

Backman

1990

Proceedings of the Ocean Drilling Program, 115 Scientific Results

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The principal paleoceanographic objective of Ocean Drilling Program Leg 115 was to collect a suite of materials that would allow reconstruction of the dynamic features of the late Cenozoic carbonate system in the equatorial Indian Ocean. This goal was achieved with the recovery of sediments from a closely spaced depth transect (1541-4428 m) of five sites (Sites 707 through 711) from on and around the Mascarene Plateau that record the last 50 m.y. of pelagic deposition. More than 2200 measurements of carbonate content are combined here with a highly resolved bio-and magnetostratigraphy to produce the first detailed compilation of bulk, carbonate, and noncarbonate mass accumulation rates (MARs) from the Indian Ocean.These results allow us to recognize three major depositional intervals, each characterized by a distinct depth-dependent pattern of carbonate accumulation: (1) the Paleogene, a time of moderate accumulation rates (0.4-0.7 g/cm 2 /1000 yr) and reduced between-site accumulation differences; (2) the early and middle Miocene, a period characterized by greatly reduced carbonate MARs (typically <0.2 g/cm 2 /1000 yr) at all sites and a shallow carbonate compensation depth; and (3) the late Miocene to Holocene, a time span marked by the highest bulk and carbonate accumulation rates of the last 50 Ma (1.6-1.8 g/cm 2 /1000 yr), and the first appearance of substantial contrasts in carbonate accumulation as a function of the water depth of the drill site. The fundamentally different character of the carbonate system during each of these intervals must represent a regional response to the complex evolution of late Cenozoic oceans and climate. INTRODUCTIONAfter a successful drilling cruise in the tropical Indian Ocean, the JOIDES Resolution returned to port at the end of Ocean Drilling Program (ODP) Leg 115 almost 40 yr to the day after the Swedish Deep Sea Expedition began its circumglobal voyage with Albatross in July 1947. That earlier expedition brought home piston cores, unique at the time, that Arrhenius (1950Arrhenius ( , 1952) first used to measure and describe time-dependent variability in the biogenic carbonate content of deep-sea sediments, variability which he attributed to rhythmic changes in ocean circulation and surface-water productivity caused by climatic forcing.During the decades that have passed since Arrhenius's pioneering work on the Albatross cores, it has become increasingly clear that the development of well-constrained models of the deep-sea carbonate budget is a necessary prerequisite to understanding the history of both ocean circulation and global climate. This insight is derived from the fact that carbonate accumulation in open-ocean environments is primarily dependent upon the production rate of planktonic foraminifers and calcareous nannoplankton in the surface waters and their subsequent dissolution on the seafloor. Surface-water productivity is determined by the availability of nutrients, whereas dissolution is largely a function of the calcium carbonate saturation state of ...

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Section: Discussionsupporting

confidence: 74%

Section: Introductionmentioning

confidence: 99%

Late Cenozoic Carbonate Accumulation and the History of the Carbonate Compensation Depth in the Western Equatorial Indian Ocean

Peterson¹,

Backman

1990

Proceedings of the Ocean Drilling Program, 115 Scientific Results

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“…Second, around the Congo estuary, the Congo Canyon immediately off Congo's west coast serves as a conduit for turbidity currents to carry away sediments from the Congo River to the oceans [53]. In addition, the branch of the northward flowing Benguela Current along the west coast of Africa can reduce sediment depositions on the northern side of the Congo River estuary [54], which may cause the potential MAR signal to emerge north of Congo's estuary in Figure 10b. Again, the GRACE data quality is another deciding factor: it is likely that GRACE data uncertainties in some of the estuaries in Figure 10 are so overwhelming that they suppress potential MAR signals.…”

Section: Discussion: Can We Detect Mars By Grace In the World's Majormentioning

confidence: 99%

Sediment-Mass Accumulation Rate and Variability in the East China Sea Detected by GRACE

et al. 2016

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Abstract:The East China Sea (ECS) is a region with shallow continental shelves and a mixed oceanic circulation system allowing sediments to deposit on its inner shelf, particularly near the estuary of the Yangtze River. The seasonal northward-flowing Taiwan Warm Current and southward-flowing China Coastal Current trap sediments from the Yangtze River, which are accumulated over time at rates of up to a few mm/year in equivalent water height. Here, we use the Gravity Recovery and Climate Experiment (GRACE) gravity products from three data centres to determine sediment mass accumulation rates (MARs) and variability on the ECS inner shelf. We restore the atmospheric and oceanic effects to avoid model contaminations on gravity signals associated with sediment masses. We apply destriping and spatial filters to improve the gravity signals from GRACE and use the Global Land Data Assimilation System to reduce land leakage. The GRACE-derived MARs over April 2002-March 2015 on the ECS inner shelf are about 6 mm/year and have magnitudes and spatial patterns consistent with those from sediment-core measurements. The GRACE-derived monthly sediment depositions show variations at time scales ranging from six months to more than two years. Typically, a positive mass balance of sediment deposition occurs in late fall to early winter when the southward coastal currents prevail. A negative mass balance happens in summer when the coastal currents are northward. We identify quasi-biennial sediment variations, which are likely to be caused by quasi-biennial variations in rain and erosion in the Yangtze River basin. We briefly explain the mechanisms of such frequency-dependent variations in the GRACE-derived ECS sediment deposition. There is no clear perturbation on sediment deposition over the ECS inner shelf induced by the Three Gorges Dam. The limitations of GRACE in resolving sediment deposition are its low spatial resolution (about 250 km) and possible contaminations by land hydrological and oceanic signals. Potential GRACE-derived sediment depositions in six major estuaries are presented.

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“…Dating of the build-up of large ice-sheets on the Antarctic continent, with their strong feedback effects on the climatic development of the total globe, is still controversial (Hsu et al, 1984;Kennett, 1980;Webb et al, 1984;Robin, 1988).…”

Section: Introductionmentioning

confidence: 99%

Eocene and Oligocene Sporomorphs and Dinoflagellate Cysts from Leg 113 Drill Sites|Weddell Sea|Antarctica

Mohr¹

1990

Proceedings of the Ocean Drilling Program

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South Atlantic Cenozoic Paleoceanography

Cited by 5 publications

References 21 publications

Late Cenozoic Carbonate Accumulation and the History of the Carbonate Compensation Depth in the Western Equatorial Indian Ocean

Late Cenozoic Carbonate Accumulation and the History of the Carbonate Compensation Depth in the Western Equatorial Indian Ocean

Sediment-Mass Accumulation Rate and Variability in the East China Sea Detected by GRACE

Eocene and Oligocene Sporomorphs and Dinoflagellate Cysts from Leg 113 Drill Sites|Weddell Sea|Antarctica

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