Ch 6

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Transcript Ch 6 

Back into the Icehouse
GEOL 3100
Christina Gallup
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Slipping into an Icehouse
• Evidence for cooling in Antarctica?
– Ice-rafted debris at 35 Ma show beginning of
ice cap
• Big jumps in ice cap size at 13 and 7-5 Ma
• Today 90% of continent covered in ice
– Beech trees and ferns lived there at 40 Ma
• lichen and summer algae today
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Antarctic cooling
55 Ma
Today
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Slipping into an Icehouse
• Evidence for cooling in the Arctic?
– Ice caps?
• NO!! Ice caps cannot form in the open ocean
– Breadfruit until 60 Ma
– Boreal forest by 20 Ma
– Tundra last few million years
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Arctic cooling
Tundra today
Broadleaf trees 55 Ma
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Slipping into an Icehouse
• Evidence for cooling in the mid to upper
latitudes?
– Greenland ice cap starting 7-3 Ma
– N. American and Eurasian ice sheets starting
2.7 Ma
• Increased in size starting at 0.9 Ma
– Mountain glaciers in the Andes starting 7-4
Ma
– Leaf outlines in western North America
transitioned from smooth to more serrated in
the last 55 Ma
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Cooling estimated from leaf shape
~10-15 C in last 50 Ma
Activity: What would allow you to evaluate the precision of this estimate?
ERROR BARS
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Oxygen Isotope
evidence for deep
water cooling over
last 70 Ma – the
deep ocean has
cooled by at least
14 degrees C
Assignment: Read
the handout and
start the homework
and we will go over
oxygen isotope
systematics next
time
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What caused the cooling: Testing
Hypotheses
• Activity: What are the main hypotheses
that we need to test?
– Polar position Hypothesis
– Spreading Rate Hypothesis
– Uplift Weathering Hypothesis
– Ocean Heat Transport Hypothesis
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Polar Position
Hypothesis:
When there are continents in
polar position, there will be an
icehouse and when there are
not continents in polar
position, there will be a
greenhouse.
Where was Antarctica at 100
Ma?
Where is it today?
How does the polar position
hypothesis do?
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Spreading Rate
Hypothesis:
When spreading is slower,
there will be cooling or in an
icehouse and when spreading
is faster, there will be warming
or a greenhouse.
Were spreading rates at 50 Ma
faster or slower than today?
Are spreading rates for the last
50 Ma consistent with cooling
for the last 50 Ma?
How does the spreading rate
hypothesis do?
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Uplift Weathering Hypothesis
•
To evaluate, need to look at
1. Evidence for uplifted terrain
2. Evidence that terrain was rapidly physically
weathered
3. Evidence that physical weathering led to
rapid chemical weathering
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High Terrains today
4 main uplifted regions today that are not covered by ice
Most of these include uplifted 100-65 Ma marine sediments
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Mountain building geologic
processes
• Activity: What are they?
– Continent-continent collision
– Subduction
– Continental rifting
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Collision of India with Asia
Tibetan plateau includes 2,000,000 sq. km with
average elevation > 5 km
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Continental Collision History
• India-Asia collision first continental
collision since 250 Ma
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Subduction related mountains
• Andes
– Subduction started before 100 Ma
– Altiplano plateau and Eastern Andes created
in last 55 Ma
• Western North America
– Subduction for last 200 Ma
– Rockies timing questionable
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Continental rifting
• East African rift in last 30 Ma
• Similar or greater African rifting at 100 Ma
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Uplift Weathering 1: uplift
• Where do we stand?
- For the three different processes of mountain
building we identified, which argue for
increased uplift in the last 55 Ma?
- Continent-continent collision!
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Uplift Weathering 2: Physical
Weathering
• What is the best evidence for increased
physical weathering in the geologic
record?
– Sediments!
– The more physical weathering, the more
detritus is created and delivered to basins
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Sediments in Indian
Ocean from
weathering of
Himalayan
mountains
Would sediments
coming off of
subduction related
mountains be as
well preserved?
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Delivery of sediments increased by monsoon rains that
are amplified by the high plateau
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Uplift Weathering 3: Chemical
Weathering
• What is the best evidence for increased
chemical weathering?
– Dissolved ions in rivers
– Hard to measure today, even harder to
quantify in the geologic past!!!
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Uplift Weathering Hypothesis
1. Sufficient uplift to drive cooling in last 50 Ma?
 Yes, Himalayas and Tibetan Plateau
2. Sufficient physical weathering to drive cooling
in last 50 Ma?
 Probably, though sediments from subduction zones
lost to trenches
3. Sufficient hydrolysis to drive cooling in last 50
Ma?
 Probably, by inference from #2
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A more
complete
climate
feedback
loop for the
upliftweathering
hypothesis
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Ocean Heat Transport Hypothesis
• Background: Increased ocean heat
transport kept poles warmer during
greenhouse
• Hypothesis: Continued high ocean heat
transport contributed to polar cooling
during the last 55 Ma
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Opening of
Drake’s
Passage ~2520 Ma may
have
decreased
oceanic
poleward heat
transport
After opening,
circumpolar
current started
No major
climate shifts
at this time
however
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Closure of
Isthmus of
Panama ~4
Ma caused
increased
poleward
heat
transport
Major
Northern
Hemisphere
glaciations
started ~1
Ma later
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Ocean Heat Transport Hypothesis
• The history of oceanic circulation and the
role of gateways in oceanic circulation still
too poorly known to evaluate the
hypothesis well.
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The Schrag Hypothesis
• Hypothesized by Dan Schrag (Harvard) in
the last few years
• The more limestone bearing oceanic crust
being subducted, the more CO2 released
into the atmosphere – Greenhouse
• The less limestone bearing oceanic crust
being subducted, the less CO2 released
into the atmosphere - Icehouse
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How does the Schrag Hypothesis
stack up?
• The ocean crust that was subducted while
India was moving towards Asia was very
limestone rich
• Most subduction zones today are not
subducting limestone bearing oceanic
crust
• The cooling started after India collided with
Asia, 55 Ma ago.
– Coincidence? Maybe not
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Many possible hypotheses
and feedbacks!
-where would the Earth go
next on a tectonic timescale,
a deeper icehouse or a
greenhouse?
-will anthropogenic global
warming affect this future?
Paleoclimatology is a very
young field and we have a
lot to learn!!
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