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Sealevel change

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Sequence stratigraphy concepts. Marine sequence stratigraphy. Nonmarine sequence stratigraphy ... impact on the stratigraphic evolution of numerous ... – PowerPoint PPT presentation

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Title: Sealevel change


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Contents
  • Introduction
  • Sedimentology concepts
  • Fluvial environments
  • Deltaic environments
  • Coastal environments
  • Offshore marine environments
  • Sea-level change
  • Sequence stratigraphy concepts
  • Marine sequence stratigraphy
  • Nonmarine sequence stratigraphy
  • Basin and reservoir modeling
  • Reflection

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Sea-level change
  • Relative sea-level change includes a global
    component (eustasy) that is uniform worldwide and
    can be measured relative to a fixed datum (e.g.,
    the center of the Earth), and regional to local
    components (isostasy, tectonism) that are
    spatially variable
  • Eustasy involves changes in ocean-basin volume,
    as well as changes in ocean-water volume
    (amplitudes 101102 m)
  • Tectono-eustasy (time scales of 10100 Myr)
  • Glacio-eustasy (time scales of 10100 kyr)
  • Isostasy refers to crustal movements that are a
    direct result of loading and unloading by ice or
    water
  • Glacio-isostasy
  • Hydro-isostasy

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Sea-level change
  • Relative sea-level change includes a global
    component (eustasy) that is uniform worldwide and
    can be measured relative to a fixed datum (e.g.,
    the center of the Earth), and regional to local
    components (isostasy, tectonism) that are
    spatially variable
  • Eustasy involves changes in ocean-basin volume,
    as well as changes in ocean-water volume
    (amplitudes 101102 m)
  • Tectono-eustasy (time scales of 10100 Myr)
  • Glacio-eustasy (time scales of 10100 kyr)
  • Isostasy refers to crustal movements that are a
    direct result of loading and unloading by ice or
    water
  • Glacio-isostasy
  • Hydro-isostasy

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Sea-level change
  • Tectonism includes a vast array of crustal
    movements, ranging from large-scale uplifts and
    basins to small-scale faults
  • Steric sea-level changes include density changes
    (temperature, salinity) and dynamic changes
    (atmospheric pressure, ocean currents, wind
    set-up), but these changes are typically on the
    order of a few meters at the most
  • The geoid exhibits lows and highs relative to the
    oblate spheroid due to gravity anomalies geoidal
    changes do occur over time, but they are most
    likely slow

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Sea-level change
  • Since isostasy and tectonism are spatially
    variable, every geographic location has a unique
    relative sea-level history (RSLEIT)
  • Four characteristic RSL-curves associated with
    the last deglaciation
  • Near-field sites (e.g., Hudson Bay)
  • Ice-margin sites (e.g., Norwegian coast)
  • Intermediate-field sites (e.g., mid-Atlantic
    coast)
  • Far-field sites (most of the southern hemisphere)

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Sea-level change
  • Since isostasy and tectonism are spatially
    variable, every geographic location has a unique
    relative sea-level history (RSLEIT)
  • Four characteristic RSL-curves associated with
    the last deglaciation
  • Near-field sites (e.g., Hudson Bay)
  • Ice-margin sites (e.g., Norwegian coast)
  • Intermediate-field sites (e.g., mid-Atlantic
    coast)
  • Far-field sites (most of the southern hemisphere)

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Sea-level change
  • It is believed that eustatic cycles of different
    periods have operated throughout the Phanerozoic
  • First-order (108 yr) and second-order (107 yr)
    cycles (primarily tectono-eustatic)
  • Third-order (106 yr) cycles (mechanism not well
    understood)
  • Fourth-order (105 yr) and fifth-order (104 yr)
    cycles (primarily glacio-eustatic)
  • Glacio-eustasy has only controlled limited
    portions of Earth history (e.g., the
    Carboniferous or Late Cenozoic icehouse world as
    opposed to the Cretaceous greenhouse world)
  • Whereas RSL change has a profound impact on the
    stratigraphic evolution of numerous sedimentary
    environments (certainly deltaic, coastal, and
    marine), the complex spatial pattern of RSL
    change commonly yields responses that are out of
    phase

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Sea-level change
  • It is believed that eustatic cycles of different
    periods have operated throughout the Phanerozoic
  • First-order (108 yr) and second-order (107 yr)
    cycles (primarily tectono-eustatic)
  • Third-order (106 yr) cycles (mechanism not well
    understood)
  • Fourth-order (105 yr) and fifth-order (104 yr)
    cycles (primarily glacio-eustatic)
  • Glacio-eustasy has only controlled limited
    portions of Earth history (e.g., the
    Carboniferous or Late Cenozoic icehouse world as
    opposed to the Cretaceous greenhouse world)
  • Whereas RSL change has a profound impact on the
    stratigraphic evolution of numerous sedimentary
    environments (certainly deltaic, coastal, and
    marine), the complex spatial pattern of RSL
    change commonly yields responses that are out of
    phase
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