Week 08 Ice Sheets & Climate Change PDF

Summary

This document covers physical geography, focusing on ice sheets, climate change, Wisconsin glacial history, and periglacial landscapes. It includes learning objectives, descriptions of glacial-interglacial cycles, Milankovitch cycles, and various feedback mechanisms. The document includes graphs, diagrams and other relevant visual information that are related to the key topics.

Full Transcript

Physical Geography: Ice
Sheets and Climate
Change, Wisconsin
Glacial History, and
Periglacial Landscapes
10/21/2024-10/23/2024
PROFESSOR PETE PULEO

1
Ice Sheets and
Climate Change

2
Learning Objectives
Explain the timing of glacial-interglacial cycles over the last ~2.6 million
years.

Explain the differences in CO2, temperature, sea level, and ice cover
between glacial and interglacial periods.

Explain the main forcings and feedbacks driving glacial-interglacial
transitions

Describe the archive and proxy records that reconstruct glacial-
interglacial cycles

3
 Pleistocene Epoch
Pleistocene Epoch is just before our present
Holocene Epoch

Spans 2.6 million years ago (Ma/Myr) to 11.7
thousand years ago (Ka/Kyr).

Earth’s Climate Past and Future by Ruddiman 3rd Ed

4
 Pleistocene Epoch
41 kyr glacial - interglacial cycles between 2.7-0.8
ma

100 kyr glacial - interglacial cycles between 0.8-
0.0 ma.

Earth’s Climate Past and Future by Ruddiman 3rd Ed

5
 Glacial – Interglacial Cycles
Glacial = Lower CO2, colder, lower sea
level, more ice

Interglacial = Higher CO2, warmer,
higher sea level, less ice

https://open.oregonstate.education/climatechange/chapter/paleoclimate/

6
 Milankovitch Cycles
Primary driver or forcing of glacial – interglacial cycles

Control amount of sunlight or insolation (W/m2) which causes initial
temperature change

https://open.oregonstate.education/climatechange/chapter/paleoclimate/

7
 Milankovitch Cycles
Precession or wobble, Eccentricity, Obliquity or tilt

https://open.oregonstate.education/climatechange/chapter/paleoclimate/

8
 Milankovitch
Cycles
Precession (Wobble) = 23 kyr
Obliquity (Tilt) = 41 kyr
Eccentricity = 100 kyr

https://open.oregonstate.education/climatechange/chapter/paleoclimate/

9
CO2 – Forcing or Feedback?
Mostly a feedback because they often lag T changes

10
GHG Feedback: CO2 Solubility
Decreasing Temperature -> Colder Water -> More CO2 drawdown from
atmosphere -> Decreasing Temperature

More CO2
Cooling Drawdown into Cooling
Ocean

Positive Feedback

11
 GHG Feedbacks: Permafrost
Positive Feedback

https://www.thearcticinstitute.org/global-carbon-budget-permafrost-feedback-
loops-arctic/

12
GHG Feedback: Iron
Fertilization
Cold, Dry Conditions -> Increased Dust -> Increased Nutrient Delivery to
Oceans -> Increased Phytoplankton -> Increased CO2 Drawdown ->
Decreasing Temperatures

Increased Dust More CO2
Cool/Dry and Nutrients to Drawdown via Cooling
Ocean Photosynthesis

Positive Feedback

13
 Ice – Albedo Feedback
Positive Feedback

https://serc.carleton.edu/details/images/17956.html

14
Big Picture: Glacial-Interglacial
Transitions
Milankovitch Cycle driven changes in energy from the Sun are
compounded on by several GHG positive feedback loops and albedo

15
 Accumulation vs. Ablation

https://www.antarcticglaciers.org/glaciers-and-climate/ice-cores/ice-core-basics/

Accumulation is the amount of snow and ice gained

Ablation is the amount of ice lost during summer melt season

Their meeting point is known as the equilibrium line

Balance of the two controls overall growth/retreat of ice sheets and glaciers

16
 Climate Factors for Ice
Sheet Growth
Summer Temperature

Precipitation as snow
(cold seasons)

Importantly, seasonal temperature and precipitation trends are vital for
understanding and predicting ice sheet change.

Summer temperature drives snow and ice loss in the summer in the ablation
zone.

Increasing temperatures can also increase the size of the ablation zone.

In the colder seasons, precipitation falls as snow over the ice sheets.

If precipitation falls as rain, it will run off the ice sheet and not contribute to
accumulation.

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 Continental Configuration
Land near poles facilitates ice sheet growth

Google Earth Pro

Plate tectonics also greatly influences ice sheet growth.

The location of continental crust near the poles is essential for forming large ice
sheets.

This provides an anchor point for ice sheets above sea level and at the coldest
places on the planet.

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 Last Interglacial – Eemian
(130-115 ka)

Dalton et al., 2022

19
Last Interglacial – Eemian
(130-115 ka)
CO2 at ~290 ppm, today is ~420 ppm

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 Last Interglacial – Eemian
(130-115 ka)
Eemian vs. Pre-Industrial (~1750 CE)

https://link.springer.com/article/10.1007/s00382-016-3274-5

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 Last Glacial Maximum (LGM)
Laurentide Ice Sheet extent

~24-20 ka

~6 degrees C cooler than
present globally

https://open.oregonstate.education/climatechange/chapter/paleoclimate/

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 End of LGM
Ice Sheet
Margin
Movement

https://surroundingtownsgeologytour.weebly.com/background.html

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 How Do We Know about Past
Climate? Paleoclimatology
The study of past climate change

https://www.usgs.gov/programs/climate-research-and-development-
program/science/paleoclimate-archives

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 How Do We Know about Past
Climate? Archives and Proxies
Archives – Geological and biological materials that record evidence of
climate change
Proxies – Measurements made on materials stored in an archive

https://www.usgs.gov/media/images/paleoclimate-archives-and-proxies

25
 Oxygen Isotopes
Isotope - Variations of an element with a different number of neutrons
(mass)

https://open.oregonstate.education/climatechange/chapter/paleoclimate/

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 Oxygen Isotopes
Fractionation – Partitioning of heavier and lighter isotopes during a
process
KE = 1/2mv2

https://open.oregonstate.education/climatechange/chapter/paleoclimate/

Because the mass of a water molecule with 18O is larger, its velocity must
be smaller to have the same kinetic energy.

Higher velocity molecules take less energy to transition from a liquid to a
gas phase and are preferentially removed.

Therefore, the heavier isotopes will remain in the liquid phase more often
than the lighter isotopes during evaporation.

This process is called fractionation, and it enables oxygen isotopes to be
used as a tracer and a climate proxy.

27
 Oxygen Isotopes In Action

https://open.oregonstate.education/climatechange/chapter/paleoclimate/

Here is a simplified diagram showing fractionation in action.

We see that oxygen isotope values of the atmosphere are depleted in heavy
oxygen compared to the ocean that it evaporated from.

Then, as the air mass moves and cools, rain forms and is enriched in 18O relative
to the air mass due to heavy water molecules preferentially raining out.

Eventually, air masses can move over ice sheets and rain out very 18O depleted
water over the ice sheets.

This means that when there is more land ice, the surface ocean water will
become enriched in 18O.

28
 Ice Core Records

https://www.antarcticglaciers.org/
glaciers-and-climate/ice-
cores/ice-core-basics/

Vostok, Antarctica ice core

29
 Marine Foram Oxygen
Isotopes
Do higher or lower d18O values correspond to glacial periods?

Ren et al., 2017

30
 Marine Foram Oxygen
Isotopes
Do higher or lower d18O values correspond to glacial periods? Higher
since ice removes 18O depleted water from the ocean

Ren et al., 2017

31
Pros and Cons of δ18O Proxy
Pros Cons
Insight on T and P Complex to interpret given
changes in temperature, moisture
Tracer for moisture source/path source/path, and precipitation
Available in several archives (trees, seasonality
ice, lake and marine sediment,
speleothems)
Available from several materials
(CaCO3, cellulose, chitin, etc.)

32
Activity 1 Description
1. Work Independently to draw and describe the timing of the
Milankovitch Cycles (Hint: 3 total). Compare with a partner after you
have made your best attempt.
2. Work with a partner to define and distinguish paleoclimate archives
and proxies while providing at least two examples for each.
3. Work with a partner to describe the major factors that influence
where/why an ice sheet forms.

33
Activity 1 Solution
1. Work Independently to draw and describe the timing of the
Milankovitch Cycles (Hint: 3 total). Compare with a partner after you
have made your best attempt.
Precession (Wobble) = 23 kyr
Obliquity (Tilt) = 41 kyr
Eccentricity = 100 kyr

34
Activity 1 Solution
2. Work with a partner to define and distinguish paleoclimate archives
and proxies while providing at least two examples for each.

Archives – Geological and biological materials that record evidence of
climate change (tree rings, ice cores, sediment cores, speleothems, etc.)
Proxies – Measurements made on materials stored in an archive (oxygen
isotopes, pollen species assemblages, sediment chemistry, etc. )

35
Activity 1 Solution
3. Work with a partner to describe the major factors that influence
where/why an ice sheet forms.

Continental configuration (where land is located due to plate tectonics
and sea level)
Summer temperatures (ablation)
Snowfall amount (accumulation)

36
Wisconsin Glacial
History

37
Learning Objectives
Summarize the history of continental glaciation in North America and
how our understanding of that history has changed over time

Describe the development of the Great Lakes

38
Thomas C. Chamberlain
(1843-1928)
Geologist that grew up in WI and taught
at UW

Studied glacial geological history of WI

Named the most recent glacial stage
the Wisconsinan, due to evidence on
the WI landscape

39
 How Do We Know Past Ice
Sheet Positions?
Glacial features like moraines can indicate extent of past glaciers

https://testbook.com/ias-preparation/moraines

40
https://www.facebook.com/wisconsinhistoricalsociety/posts/did-you-know-
wisconsin-is-right-about-in-the-middle-when-it-comes-to-land-area-
a/802194828621038/

41
Laurentide Ice Sheet
Movement
https://youtu.be/rq90Qv0-tbo

42
https://www.wisconsinwetlands.org/updates/wisconsin-wetlands-the-ice-age-
connection/

43
 Glacial Depressions ->
Wetlands
Green = Wetland areas

Corresponds to ice sheet
movement

https://www.wisconsinwetlands.org/updates/wisconsin-wetlands-the-ice-age-
connection/

44
Glacial Extent

45
https://www.britannica.com/science/Wisconsin-Glacial-Stage

46
 Ecological Development

http://sciencebitz.com/?page_id=41

47
 Ice Age Animals of the
Midwest
Woolly mammoths, muskox, and caribou fed on
tundra vegetation

Sabertoothed cats were apex predators

https://home.

https://iceage.museum.state.il.us/mammals/sabertoothed-
catswgnhs.wisc.edu/wisconsin-geology/ice-age/

48
49
 The Great Lakes: Volume
21% of world’s surface freshwater

https://bobby-c-blog.com/2013/09/06/great-lakes-volume-math/

50
 The Great Lakes: Average Depth

https://en.wikipedia.org/wiki/Great_Lakes

51
 The Great Lakes: Elevation + Flow

https://vividmaps.com/great-lakes-profile/

52
 The Great Lakes: Bathymetry

https://commons.wikimedia.org/wiki/File:Great_Lakes_bathymetry_map.png

53
 Prerequisites for The Great
Lakes
Lake Superior was a failed rift
valley (Midcontinental Rift)

Led to basin development

https://en.wikipedia.org/wiki/Midcontinent_Rift_System

54
Prerequisites for The Great
Lakes
Lake Michigan and Huron were covered with soft rock that was easily
eroded by the Laurentide Ice Sheet

55
 Forming the Great Lakes
The Laurentide Ice Sheet excavated the lowlands, leaving behind deep
basins that filled with meltwater

https://www.seagrant.wisc.edu/resources/the-formation-of-the-great-
lakes/how-they-were-made/

56
The Great Lakes: Water Level
and Flow Path Change

57
 The Great Lakes: Isostatic
Rebound

https://www.usgs.gov/media/images/glacial-isostatic-adjustment

58
 The Great Lakes: Isostatic
Rebound

https://en.wikipedia.org/wiki/Post-glacial_rebound

59
Activity 2 Description
Independently visit the following website
(https://wgnhs.wisc.edu/pubshare/ES056.pdf) that describes the glacial
history of Wisconsin and answer the following questions.

1) When did glacial Lake Scuppernong exist on the SE WI landscape?
2) When did glacial Lake Wisconsin exist in the central WI landscape?
3) When did glacial Lake Oshkosh form in NE WI (Hint: several times)?
4) How do we know where glacial lakes existed?

60
Activity 2
Solution
1) When did glacial Lake
Scuppernong exist on
the SE WI landscape?

26,500 – 24,500 years
ago and 18,500 – 16,000
years ago

61
Activity 2
Solution
2) When did glacial Lake
Wisconsin exist in the
central WI landscape?

28,500 – 27,500 years
ago and 24,000 –
19,000 years ago

62
Activity 2
Solution
3) When did glacial
Lake Oshkosh form
in NE WI (Hint:
several times)?

31,500, 26,000,
18,000, and 13,000
years ago

63
Activity 2 Solution
4) How do we know where glacial lakes existed?
The geologic evidence for these former lakes is the distribution of lake
sediment on the landscape.
A few places also have beach deposits associated with past lake
shorelines.

64
Periglacial
Landscapes

65
Learning Objectives
Discuss the nature and distribution of permafrost

Explain the processes that shape periglacial landscapes

Describe the major landforms of periglacial regions

Briefly review the broader importance of periglacial environments

66
Periglacial
Environments near glaciers or in very cold climates

67
 Periglacial Extent

https://learningglaciers.blogspot.com/2012/09/an-introduction-to-
periglacial.html

68
Permafrost
Permanently frozen ground

69
Permafrost
Permafrost Table – Upper surface of permafrost

70
Permafrost
Active Layer – Soil subject to freezing and thawing annually

71
Permafrost
Talik – Unfrozen zone under lake and above permafrost

72
Permafrost
Types
Continuous – Largely
unbroken, thick permafrost

73
Permafrost
Types
Discontinuous – Generally
thin with many unfrozen
areas

74
Permafrost
Types
Alpine – High elevation
permafrost at lower latitudes

75
Permafrost and Water
Frozen water is impermeable meaning water doesn’t flow through it
Why would that matter?

76
Permafrost and Water
Frozen water is impermeable meaning water doesn’t flow through it
Why would that matter?
Causes water to pool on surface

77
Permafrost and Water
Typically, water can percolate through soil in the active layer but doesn’t
go through the impermeable permafrost

78
Frost Action or Wedging
A type of mechanical weathering involving the freezing and expansion
of water

79
 Frost Heaving
When soils freeze and expand, overlying material gets forced upward

https://www.researchgate.net/figure/Schematic-of-evolution-of-frost-heave-
from-unsaturated-through-saturated-state-at-the_fig1_327559981

80
 Frost Creep
Mass movement of
particles in the active
layer downslope
from gravity

http://www.physicalgeography.net/fundamentals/10ag.html

81
Solifluction
Slow flow of water saturated soil over permafrost

82
Solifluction
Less likely with porous soils with a lot of space between particles
(sand/gravel)

83
Periglacial Landforms: Ice
Wedges
Ground contracts/cracks in winter
and is filled in by water in the
summer which eventually freezes

Leads to polygons on surface
(requires permafrost)

84
Periglacial Landforms:
Patterned Ground
Rock and soil debris sorted in a manner
that resembles rings, polygons, lines, or
other patterns

85
Periglacial Landforms:
Patterned Ground
Thought to be from freeze-thaw cycles (frost heaving and gravity)

86
Periglacial Landforms: Pingos
Mounds on landscape up to 600 m in diameter and 60 m high

87
 Periglacial
Landforms: Pingos
Form from water lenses in the
soil freezing and lifting soil
above

https://www.britannica.com/science/pingo

88
Periglacial Landforms:
Blockfields
Large areas covered in blocky boulders from frost action/wedging and
mass movement

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Activity 3 Description
Work with a partner to answer the following questions. Prepare to
share your answers.

1) Why are wet, saturated soils common in periglacial environments
even though precipitation there is relatively low?
2) What is the distinction between continuous and discontinuous
permafrost? Where are they located relative to one another on Earth?
3) What is a pingo? How do pingos form? Provide a drawing and a
written description.

90
Activity 3 Solution
1) Why are wet, saturated soils common in periglacial environments
even though precipitation there is relatively low?

Permafrost prevents adequate drainage, trapping water in the active
layer and keeping soils saturated

91
Activity 3 Solution
2) What is the distinction between continuous and discontinuous
permafrost? Where are they located relative to one another on Earth?

Continuous permafrost has frozen soil everywhere in the area whereas
discontinuous permafrost has frozen soil in some areas.
Continuous permafrost occurs at higher latitudes or higher elevations
compared to discontinuous permafrost since it requires a colder
climate.

92
Activity 3
Solution
3) What is a pingo? How do
pingos form? Provide a
drawing and a written
description.
A pingo is a mound in a
periglacial landscape.
Water drains into the soil
after the active layer
thaws. Then, that water
lens freezes and lifts the
soil above.

93
 Multiple Choice Practice Qs
Take ~ 1 minute to independently think about and write down an answer to the
question on the board.

Then, turn to a partner and discuss your reasoning for choosing that answer.

Write a second answer after you have discussed your thoughts with a partner (its
okay to write the same answer twice or change your answer, just be sure to have two
answers per question).

Finally, we will discuss the correct answer as a class.

Be sure to have your name and date on top and hand in before you leave.

94
Question 1
What primarily drives the glacial-interglacial cycles?
A) Greenhouse gases
B) Milankovitch cycles
C) Ice-albedo feedback
D) Sun’s brightness

95
Solution 1
What primarily drives the glacial-interglacial cycles?
A) Greenhouse gases
B) Milankovitch cycles
C) Ice-albedo feedback
D) Sun’s brightness

96
Question 2
What primarily causes ice sheet ablation?
A) Warm summers
B) Dry winters
C) Dry summers
D) Warm winters

97
Solution 2
What primarily causes ice sheet ablation?
A) Warm summers
B) Dry winters
C) Dry summers
D) Warm winters

98
Question 3
What former glacial lake existed in present day Whitewater?
A) Glacial Lake Wisconsin
B) Glacial Lake Oshkosh
C) Glacial Lake Whitewater
D) Glacial Lake Scuppernong

99
Solution 3
What former glacial lake existed in present day Whitewater?
A) Glacial Lake Wisconsin
B) Glacial Lake Oshkosh
C) Glacial Lake Whitewater
D) Glacial Lake Scuppernong

100
Question 4
Permafrost:
A) Is more common in the Southern Hemisphere that the Northern
Hemisphere
B) is primarily discontinuous north of the Arctic Circle
C) is not currently present in Alaska
D) extends further south during periods of extensive glaciation

101
Solution 4
Permafrost:
A) Is more common in the Southern Hemisphere that the Northern
Hemisphere
B) is primarily discontinuous north of the Arctic Circle
C) is not currently present in Alaska
D) extends further south during periods of extensive glaciation

102
Question 5
In what permafrost layer would you expect to find the most rocks broken
down by frost wedging?
A) Active layer
B) The permafrost table
C) Where permafrost meets bedrock
D) Permanently frozen ground at moderate depths

103
Solution 5
In what permafrost layer would you expect to find the most rocks broken
down by frost wedging?
A) Active layer
B) The permafrost table
C) Where permafrost meets bedrock
D) Permanently frozen ground at moderate depths

104
Question 6
Which term describes the movement of water-saturated soil downslope
above permafrost?
A) Glacial plucking
B) Solifluction
C) Frost wedging
D) Frost heaving

105
Solution 6
Which term describes the movement of water-saturated soil downslope
above permafrost?
A) Glacial plucking
B) Solifluction
C) Frost wedging
D) Frost heaving

106