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Marine Provinces

Marine Provinces. Bathymetry. Bathymetry is the measurement of ocean depths and the charting of the shape or topography of the ocean floor The ocean floor is a highly varied terrain that contains many interesting features Early methods used a long weighted line (called a sounding line).

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Marine Provinces

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  1. Marine Provinces

  2. Bathymetry • Bathymetry is the measurement of ocean depths and the charting of the shape or topography of the ocean floor • The ocean floor is a highly varied terrain that contains many interesting features • Early methods used a long weighted line (called a sounding line)

  3. Bathymetric techniques • Echosounders send sound through water to determine water depth and sea floor features

  4. Bathymetric techniques • Side-scan sonar uses a “fish” towed behind a ship to give a more detailed picture of the sea floor

  5. Bathymetric techniques • Low frequency sound is used to determine structure beneath the sea floor

  6. Bathymetric techniques • Satellites measure sea surface elevation, which mimics sea floor bathymetry

  7. Topography of the Ocean Floor Continental Margin- submerged outer edge of the continent. Includes the continental shelf and slope.

  8. Continental shelf • Continental slope • Continental rise • Abyssal plain • Abyssal hills • Features of the Underwater World • Submarine canyon • Seamount • Guyot • Ridge • Trench

  9. slope continental shelf rise abyssal plain abyssal hills ridge transform fault

  10. Continental Shelf: • shallow submerged extension of the continent • more like the continent than the ocean basin • important for mineral and oil deposits • 7.4% of Earth’s ocean area

  11. Continental slope: • the transition between the gently descending cont. shelf and deep-ocean basin • generally, 4 - 25o slope, 12 miles wide, 12,000ft deep • Continental Rise: • accumulation of sediment from turbidity currents • like an avalanche

  12. Shelf width depends on: • proximity to plate boundary (passive vs active margin) • sea level • fast moving ocean currents

  13. Proximity to Plate Boundary

  14. Passive versus active continental margins • Passive margin • No plate boundary • Shelf • Slope • Rise • E.g., eastern coasts of N. and S. America • No volcanism

  15. Passive versus active continental margins • Active margin • Plate boundary • Convergence zone • volcanism, many earthquakes, and active mountain building • E.g., California, Chilean (e.g., Peru, Chile), Marianas (e.g., Japan, Marianas)

  16. Sea Level Change

  17. Fast Moving Ocean Currents

  18. Abyssal plain: • flat featureless expanses of sediment formed by suspension settling • common in Atlantic • Abyssal hills: • small sediment covered extinct volcanoes • < 650 ft high

  19. Sea mount: • volcanic projections that don’t rise above the surface of the sea • circular or elliptically shaped • many form at hot spots

  20. Guyot: flat topped sea mounts

  21. Submarine canyons: • Canyons that cut into continental shelf • Turbidity currents carve submarine canyons into the slope and shelf

  22. Submarine canyons and deep-sea fans • Moves sediment movement from the continents into the deep-sea via turbidity currents • Debris from turbidity currents creates graded bedding deposits and deep-sea fans

  23. Diver in the La Jolla Submarine Canyon

  24. Ridges: mountainous chain of young basaltic rock at the active spreading center of the ocean

  25. The Mid-Atlantic Ridge • Traverses the center of the Atlantic Ocean • Contains a central down-dropped rift valley • Surfaces in Iceland

  26. Features of the mid-ocean ridge • Rift valleys • Form when plates split apart • Down-dropped areas associated with faults and earthquakes

  27. Trenches: arc-shaped depression in the deep ocean floor • Formed by plate convergence • Associated with volcanic arcs • Island arc • Continental arc • Most active geologic feature on earth

  28. Ocean trenches • Most trenches are in the Pacific Ocean

  29. Location of Marianas Trench

  30. Location of Mariana Trench

  31. Ocean sediment • Particles of organic or inorganic matter that settle through the water column and accumulate in a loose, unconsolidated form on the ocean floor • Layers represent a record of Earth history, including: • Movement of tectonic plates • Past changes in climate • Ancient ocean circulation patterns • Cataclysmic events

  32. Collecting ocean sediment • Specially designed ships collect cores by rotary drilling • Cores allow scientists to analyze ocean sediment

  33. Sediment origin & composition • Origin: • Weathering and erosion • Activity of living organisms • Accumulation of dead organisms- oozes • Volcanic eruptions • Chemical processes within the water itself • Space debris • Composition: • Boulder >256mm Sand 0.062-2mm • Cobble 64-256mm Silt 0.004-0.062mm • Pebble 4-64mm Clay <0.004 • Granule 2-4mm

  34. Sources of Sediment • Terrigenous: • Continental runoff- desert sand blows off continent to ocean • Volcanic eruptions- dust and magma • Rivers- washout of sediment Mt. St. Helens

  35. Biogenous: • Mostly calcareous and siliceous • Abundant where ample nutrients encourage high biological productivity • Parrotfish • Oozes: pelagic sediment • containing >30% by volume • microorganism shells

  36. Biogenous sediment composition • Microscopic biogenous tests are composed of 2 main chemical compounds: • Silica (SiO2) including opal (SiO2 · nH2O) • Diatoms (algae) • Radiolarians (protozoan) • Calcium carbonate or calcite (CaCO3) • Coccolithophores (algae) • Foraminifers (protozoan)

  37. Calcareous Oozes Coccolithophores Foraminifers pteropod

  38. Siliceous Oozes radiolarian diatom

  39. Biogenous ooze turns to rock • When biogenous ooze hardens and lithifies, can form: • Diatomaceous earth (if composed of diatom-rich ooze) • Chalk (if composed of coccolith-rich ooze) Chalk cliffs of southern England

  40. Distribution of biogenous ooze • Most biogenous ooze found as pelagic deposits • Factors affecting the distribution of biogenous ooze: • Productivity (amount of organisms in surface waters) • Destruction (dissolving at depth) • Dilution (mixing with lithogenous clays)

  41. Hydrogenous sediment • Hydrogenous sediment forms when dissolved materials come out of solution (precipitate) • Precipitation is caused by a change in conditions including: • Changes in temperature • Changes in pressure • Addition of chemically active fluids

  42. Types of hydrogenous sediment • Manganese nodules • Phosphates • Carbonates • Metal sulfides • Evaporite salts

  43. Magnesium nodules: • 1st discovered by Challenger expedition (1873-76) • 16 million tons accumulate each year • Growth rate: 1-10 mm/million years • Need nuclei to form • Mining has not developed because: • Low international market price for metals • Unresolved legal ownership problems • Technical costs and development • Effect on hydrothermal vent communities unknown Mining manganese nodules

  44. Cosmogenous sediments: • Extraterrestrial in origin • Two main types: • Microscopic space dust • Macroscopic meteor debris Diatoms (algae) • Forms an insignificant proportion of ocean sediment tektites

  45. Studying sediments • Learn about past climates • Ocean circulation • Plate tectonics • O2 isotope stratigraphy: • O216 (most abundant): O218 (next abundant) • O216 has higher vapor pressure • At a given time when a shell forms in cold water, more O218 goes in relative to O216

  46. Map of the World Ocean showing generalized distribution of the principal kinds of sediment on the ocean floor

  47. Deep Ocean Characteristics • Cold • Still • Stable • Dark • Essentially no productivity • Sparse Life • Extremely high pressure • Little food

  48. Potential Food Source for Deep Sea Organisms Deep sea orgs are dependant upon surface production from: • Dead phytoplankton, zooplankton, fish, mammals • Fecal pellets and crustacean molts • Macrophyte detritus • Animal migrations

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