the sea floor

seafloor water covers 70% of Earth’s surface

seafloor deep seafloor largely unknown prior to 1950’s seafloor map from Dana (1894)

seafloor oceans originated mostly from volcanic de-gassing of water vapor from Earth’s interior additional small amount may have come from late comet impacts after the Earth reached close to its current mass

studying the seafloor direct methods rock dredges sea floor drilling submersibles indirect methods sonar seismic reflection profiling

rock dredges direct methods

sediment corer direct methods

sea floor sediment core direct methods

JOIDES Resolution (1990’s-being overhauled) DSDP (Deep Sea Drilling Project); ODP (Ocean Drilling Project) …IODP (Integrated Ocean Drilling Project)…

Chikyu Japanese drill ship

submersibles manned or unmanned direct methods

sonar (sound navigation and ranging) sound sent from ship, bounced off sea floor, and recorded at ship indirect methods distance to seafloor is calculated from speed of sound in water multiplied by time to get return signal divided by two (wave goes down and up)

known for a long time that sound travels through water 1822 attempt to determine speed of sound in water indirect methods

seismic reflection indirect methods penetration of sediments by sound waves hydrophones record signals echo sounding, swath bathymetry, sidescan

sea floor profile indirect methods

South Pacific sea floor indirect methods

sea floor was critical in development of plate tectonics yellow lines are plate boundaries seafloor, continents, and plate boundaries

general profile through ocean features of the seafloor from left to right shelf, slope, abyssal plain, mid-oceanic ridge seamounts, trench, slope shelf passive continental margin (no plate boundary) active continental margin (plate boundary) mid-oceanic ridge (plate boundary)

slope angle is only 4-5° continental shelf and slope topographic profile has 25x vertical exaggeration (vertical and horizontal scales are not the same) broad, shallow shelf ( m water depth) steeper slope dives to abyssal plain

passive margin NO plate boundary at edge of continent shelf and slope continental rise (less steep than slope) abyssal plain (smooth, deep seafloor)

submarine canyons and abyssal fans start on shelf and end at base of slope allow for transport of sediment from shelf to sea floor

sand falls offshore Baja, California

submarine canyons and abyssal fans (California) “turbidity currents” flow down canyons and deposit on fans

offshore southern California

landslide triggered by earthquake submarine canyons cable breaks in different locations at different times as landslide arrives

continental rises and abyssal plains continental rise: gently sloping wedge of sediment of sediment at base of slope abyssal plain: flattest region on Earth; form where turbidity currents bury features sediments deposited by turbidity currents and contour currents move along elevation contours

active margin plate boundary at edge of continent shelf and slope oceanic trench (deepest features in ocean) volcanoes (on-land) Wadati-Benioff zone --dipping zone of earthquakes that begin at trench and extend landward (red stars)

active margins (trenches-plates converge)

mid-ocean ridge (plate boundary-plates diverge)

NORTH AMERICAAFRICA sea floor spreading (divergence) axial valley from: 80,000 km long; 1,500-2,500 km wide mid-ocean ridge elevations of 2,000-3,000 m above sea floor rift valley ~1,000 m deep at crest of ridge

basalt flows and volcanism mid-ocean ridge high heat flow and small, shallow earthquakes hot springs supporting biological communities

black smoker (first ever seen) 1979

life at oceanic ridge tube worms giant clams spider crab

explore using submersibles ALVIN was first one; 3 passenger

both from: exposed on-land in Iceland mid-ocean ridge

transform faults mid-ocean ridge fracture zones continuation of transform fault beyond ridge --no eq’s-- offset of mid-ocean ridge between adjacent ridges --earthquakes occur along them (red stars)--

transform fault--fracture zone animation green are ridge segments; red is transform fault

from:

other sea floor features seamount conical mountain that rises > 1,000 m above sea floor; basaltic volcanoes; chains of seamounts occur (aseismic ridges) (Emperor seamounts) guyot flat-topped seamount; erosion from waves; reefs common around them

seamount chains and ages of seamounts in one (hot spot track -- more later) Emperor seamounts

pelagic: accumulate by settling through water column …clays from wind; skeletons of microsopic organisms… sea floor spreading leads to greater thickness of pelagic sediments away from ridge crest (no sediment at mid-ocean ridge) sea floor sediments terrigenous: derived from land and brought to sea floor …sands/silts that make up continental rise…

composition of the oceanic crust seismic surveys suggest ~ 7 km thick with 3 layers 1) marine sediments (sampled) 2) pillow basalts (sampled) 3) gabbros (not sampled) (intrusive equivalent to basalt)

pillow basalts

resources of the ocean offshore drilling

mining the ocean floor? manganese nodules