Post on 28-Dec-2015
Geology 12Geology 12
PresentsPresents
Unit 3Unit 3Chp 10 Earth’s InteriorChp 10 Earth’s InteriorChp 11 Ocean FloorChp 11 Ocean FloorChp 12 Plate TectonicsChp 12 Plate TectonicsChp 9 Seismic (EQ)Chp 9 Seismic (EQ)Chp 13 StructureChp 13 Structure
Chp 12 Plate Tectonics• Theory is that Earth consists of about 18-20
rigid lithospheric plates that move about the Earth’s surface on a plastic asthenosphere and mantle.
• Lithosphere = crust + upper mantle (UM)
• Lithospheric plates:– Cont’l: up to 250 km thick (crust 90 + UM 160)– Oceanic: up to 100 km thick (crust 10 + UM 90)
• Move 2 – 20 cm/yr but average is 2-3 cm/yr
Chp 12 Plate Tectonics
Major Plate Boundaries
Lithospheric Plates = crust + upper Mantle
Up to 100 km thick
Up to 250 km thick
Plates move 2 – 20 cm/yr but average is 2 – 3 cm/yr
Rate of Plate MovementRate of Plate Movement
Evidence of Plate Tectonics• 1. Continental fit/jig-saw puzzle pieces
QuickTime™ and aSorenson Video 3 decompressorare needed to see this picture.
• 2. Similarity of Rocks and Mountains
• 3. Glacial Evidence: Glacial striations indicate movement of ice away from the pole
• 4. Fossil Evidence: same fresh water land fossils found on different continents
• 5. Paleomagnetism and Polar Wandering: plates moved N/S as given by magnetic inclination.
• 6. Seafloor Spreading: a 65,000 km longvolcanic mountain chain (ridge) in the oceans are where the sea floor splits and spreads apart.
5 pieces of evidence to support seafloor spreading to come
• As oceanic plates are driven apart by thermal convection cells/currents in the mantle, new oceanic crust forms in the rift.
lithosphere
mantle
• New oceanic crust is created at the ridge; old oceanic crust is destroyed as it plunges down the trenches.
6. Evidence of Seafloor Spreading• a) GPS = Global Positioning Satellites in
space give exact positions of continents; they tells us exactly how the plates are moving.
• b. Reversal of Earth’s Magnetic Field is recorded on the seafloor as iron-rich magma cools below the Curie Point to form pillow lavas and gabbro recording the Earth’s present magnetic field.
animation
• b. Reversal of Earth’s Magnetic Field is recorded on the seafloor as iron-rich magma cools below the Curie Point to form pillow lavas and gabbro recording the Earth’s present magnetic field.
Q 60, p.18 WS 12.2
To find the middle of oceanic ridge, use the “dirty diaper” model
Lab 12.1 is next…it covers magnetic striping
• c. Radiometric Dating of Oceanic Plate: youngest at ridge; older as you move away
youngold old
Oldest oceanic crust is 180 ma
Oldest continental crust is 4,000 ma (4 ba)
• c. Radiometric Dating of Oceanic Plate
c. Radiometric Dating of Oceanic Plate
d. Thickness of Sediments on Oceanic plates
• Thinnest near the ridge; thicker as you move away
Abyssal plain
Abyssal hill
Seamount
• d. Thickness of Sediments on Oceanic plates
e. Heat Flow Highest at Ridge: b/ci) Oceanic crust is thinnest at ridge = less insulation from
hot interior
ii) Oceanic crust is newly formed from molten rock = hot
4
3
2
1
0
Island arc (volcanoes)
World average
Oceanic ridge
trenchnew crustold crust
e. Heat Flow Highest at Ridge
Plate Boundaries
Please hand out WS 12.1 Note helper.Please hand out WS 12.1 Note helper.
Plate Boundaries• A. Passive Margins: where oceanic and cont’l
plates are fused and larges amount of sediment is deposited.
Cont’l PlateOceanic Plate
Cont’l Shelf Cont’l Slope Cont’l RiseAbyssal
Plain
Cont’l Margin
fused
• As oceanic plate becomes thicker, it becomes heavier, plus it gets pushed down with sediment. If/when this boundary becomes active, the sediment will be pushed into mtn’s.
Cont’l PlateOceanic Plate
Cont’l Margin
fused
i.e. like the Rockies
Plate Boundaries
• A. Passive Margins
Plate Boundaries
• B. Active Margins: where plates are moving away (#1: plate is being created), towards (#2: plate is being destroyed), or past each other (#3)
1. Divergent Boundaries/Spreading Ridge
Crust is pulled apart by convecting mantle, thins, breaks open, and magma (lower pressure lower melting temp’) wells up to form sheeted dikes of gabbro, basalt and pillow lava.
basalt
gabbromantle
rift
• Also:– High heat flow– Basaltic/mafic lava– Shallow (& mild) EQs (<30 km)– Rugged topography (seamounts, basalt
floods, pillow lava)– Starts off as
• i) doming/crustal unwrap• ii) rift valley & basalt floods• iii) narrow sea (i.e. Red, Dead) as continents split
up• iv) spreading ocean (i.e. Atlantic)
Plate Boundaries
• B. Active Margins– 1. Divergent Boundaries
Triple Junctions
– 2. Convergent Boundaries = where 2 plates collide
a) oceanic-oceanic
over
under
c u.m.Upper mantle
crust
asthenosphere
Accretionary wedge
trench Fore arc basin
Back arc basin
Volcanic isld’ arc
• Magma melting temperature lowered by water
• Deepest trenches (11 km) because both plates are heavy (3.0 gm/cm3)
• Andestic magma
• 2. Convergent Boundaries• a) Oceanic-oceanic
Accretionary Complex
Fore arc basin
Volcanic arc
Back arc basin
• Driving Force on oceanic plate is:i) pushed/dragged by convecting mantle = “ridge push”:
ii) Pulled by sinking oceanic slab in mantle = “slab-pull”:
• Deep EQs (100 - 700 km)• Ex: Aleutian Islds, Japan, Taiwan, Philippines, New Zealand, Caribbean Islds.
For
e ar
c ba
sin
Vol
cani
c ar
c
Back arc
basin
“Ridge Push – Slab Pull”
• Sediment is scraped off descending ocean floor to form: accretionary wedge = melange = subduction complex (mainly deep sea sediments/shale + pillow lavas)
WA
OR
CA
Melange
Fore arc basin
Volcanic arc
b) Oceanic-continental
O.C.U.M.
Cont’l crust
Upper mantle
asthenosphere
Folded mtn’s
Volcanic arc
Back arc basin
Fore arc basin
Accretionary wedge
trench
• Magma melting temperature lowered by water
• Andestic magma
• Driving force on oceanic plate is:– i) pushed/dragged by convecting mantle– ii) pulled by sinking oceanic slab in mantle
• Deep EQs: up top 700 km
• Ex: Nazca and S. American Plates
b) Oceanic-continental
b) Oceanic-continental
Fore arc basin
Accretionary Complex
Back arc basin
Folded Mountains
Volcanoes
• If an oceanic – continental subduction continues … it will result in:
O.C.U.M.
Cont’l crust
Upper mantle
asthenosphere
O.C.U.M.
Cont’l crust
Upper mantle
asthenosphere
Passive margin Active margin
Cont’l crust
c) continental - continental Deformed & metamorphosed
accretionary wedge
Mtn’ range
Upper mantle
asthenosphere
oceanic crust
Cont’l crustCont’l crust
U.M.
Ex: Himalayas, Alps, Urals
c) Continental-continental
2. Convergent Boundaries c) Continental-continental
3. Transform Boundary
• Where plates slide past each other
• Mainly associated with divergent boundaries
RH LH
Transform boundaryRH
•Shallow EQs <30 km
• 3. Transform Boundary
LH
Transform Faults
LH
BC Coast Tectonic Scenario
Pacific plate
North American
plate
Juan de Fuca plate
Gorda Plate
Note helper endsNote helper endsPlease use your note book now.Please use your note book now.
Interplate setting:
• Continental: during the Paleozoic (570 – 245 ma) and Mesozoic (245 – 66 ma), inland seas covered most of the continents, except mountains, so it ranged from swampy (i.e. ferns – coal at the edges of the seas in W. Alberta & Pennsylvannia, Kentucky) to inland shallow marine seas (Devonian reefs from Alberta to Texas)
Interplate Setting
Paleozoic 300 my
North America
• Mesozoic 100 my • North America
• Cenozoic (66 ma) to present, it has been mainly erosion of the continents and sedimentation on the margins.
• Oceanic setting: plates are very new, largely 2 major events occuring in the middle of the plates:– i) sedimentation (clays and ooze)– ii) hot spot volcanism (Hawaii-Emperior chain)
give absolute plate velocity.
• Wilson Cycle is 500 ma period where the Atlantic Ocean opens and closes, and continents split apart and collide to form supercontinents, over and over again.
3 times at least:Pangea: 275 myRodinia: 1000 myColumbia: 1800 my
Pangea: 275 my
Rodinia: 1000 my
Columbia: 1800 my
• 0 – 100 ma: “supercontinent” insulates mantle; heat builds creating diverging convection cells.
• 100 – 300 ma: rifting and creation of new ocean basin. New continents separated by widening ocean basin.
• 300 – 500 ma: oceanic crust becomes thicker, heavier, & sinks at passive margin becoming an active margin – subduction bdy’; continents come back together, collide and create high mtn’ chain.
• Do WS 12.2