Geography 140
Introduction to Physical Geography
Lecture: Glacial Processes
G. Glacial processes
1. Glacial processes entail the erosion, transportation, and
deposition of earth materials by moving ice.
2. Glaciers presently cover about ten percent of the earth's land
surface. At times during the Pleistocene epoch (roughly 2 million
years ago to about 14,000 years ago), they covered up to thirty
percent! You can see the extent of the Pleistocene glaciation and
its Holocene shrinkage here, as shown just for North America:
![[ Pleistocene glaciation, Holocene deglaciation in North
America, Illinois Museum ]](http://museum.state.il.us/exhibits/ice_ages/images/loopglac.gif)
3. Glaciers are classified according to size/shape/location and
temperature.
a. Size/shape/location:
i. Confined glaciers are those confined by valley walls to one
extent or another.
a. They are relatively small and found in mountainous
terrain. Confined glaciers, then, can be called alpine
glaciers, mountain glaciers, or montane glaciers.
b. They can be found at sea level at high latitudes (as in
Alaska, Scandinavia, or southern Chile) but they can
also be found right on or near the equator (Mt.
Kilimanjaro in Tanzania is glacier-covered, as are the
Andes in Ecuador). There is an inverse relationship
between latitude and elevation of confined glaciers.
c. The smallest of these confined glaciers are cirque
glaciers. These are found in concave depressions on the
higher sides of mountains, up near their crests. These
concavities are circular in shape (hence the French word
cirque). The cirques are produced by the weight
and motion of these small glaciers.
![[ cirque glacier, W.W. Locke ]](http://www.homepage.montana.edu/~geol445/hyperglac/morphology1/Cirque.jpg)
d. Valley glaciers are montane glaciers that flow down a
pre-existing valley. They are confined by the valley's
sides. They grow as smaller tributary valley glaciers
and cirque glaciers fuse together.
![[ valley glacier, J. Anderson, Rice University
]](http://www.homepage.montana.edu/~geol445/hyperglac/morphology1/ValleyGlacier.gif)
e. Branched-valley glaciers have one or more tributary
glaciers flowing onto and into it (kind of like a
higher-order stream has lower-order tributaries).
![[ branched-valley glaciers in Tadjikistan
showing looped moraines from surges, PBS Nova, space image source unattributed
]](http://www.pbs.org/wgbh/nova/sciencenow/3210/images/03-spac-tadschilooped.jpg)
f. Piedmont glaciers are valley glaciers that have spilled
out of the mountain ranges that confine their sides out
onto flat land, such as a valley, plain, or beach.
Their ends, then, are unconfined.
![[ piedmont glacier, National Snow and Ice Data
Center ]](http://web.archive.org/web/20020718070722/http://nsidc.org/glaciers/gallery/Malaspina.jpg)
g. Tidewater glaciers are those that empty out directly
into the sea. They form at such high latitudes that
they can reach down to sea level before ablating.
![[ tidewater glacier, Taku Glacier, Alaska,
National Snow and Ice Data Center ]](http://web.archive.org/web/20060518091243/nsidc.org/glaciers/gallery/images/taku_large.jpg)
ii. Unconfined glaciers are glaciers that flow over a landscape
and are not confined by it.
a. Continental ice-sheets are huge domes of ice burying an
entire continent, a significant part of a continent, or
a very large island.
1. Only two exist today:
A. Antarctican ice sheet, burying virtually all of
Antarctica, with the occasional mountain peak (or
nunatak) sticking out of it here and there. The
Antarctican ice sheet is nearly 5 km thick in
places (4,770 m)!
B. The Greenland ice sheet covers just about all of
Greenland, the gigantic island to the northeast of
Canada. In places, this ice sheet gets over 3 km
in thickness!
2. Other continental ice sheets have existed in the
past. During the Pleistocene glaciation, ice sheets
also extended out from the Rockies (Cordilleran ice
sheet), Canada (Laurentian ice sheet), the
northernmost Canadian islands (the Innuitian ice
sheet), Scandinavia and Finland (the Fenno-Scandian
ice sheet), and northern Russia (the Eurasian ice
sheet).
![[ Northern Hemisphere glaciation 18,000 bp,
Geological & Environmental Sciences, Hartwick College, Oneonta, NY ]](http://web.archive.org/web/20010607055521/http://www.hartwick.edu/geology/work/VFT-so-far/glaciers/icesheet.gif)
4. Glaciers are formed when winter or annual snow accumulation exceeds
summer melt (ablation), sublimation (evaporation of ice directly
into vapor), and iceberg calving (breaking off of peripheral ice
into the sea) over several years' time.
a. Each year's accumlation is packed down by the next year's, until
the pressure of its weight causes the snow to go through a
series of mechanical changes that eventuate in glacial ice.
i. New snow is not very dense (~50-300 kg/cubic meter),
basically consisting of the ice lattice of interlocked
snowflakes with plenty of air and maybe water vapor or even
liquid water.
![[ snowflake diagram, open2.net ]](http://www.open2.net/open2static/source/file/root/14/23/58841/snow_stages_a.jpg)
ii. As it's slowly compacted down and as the snow experiences
both melting and sublimation, the original snowflakes lose
much of their spikiness: They become more like rounded ice
crystals. This can pack down more compactly and attain
greater density (>500 kg/cubic meter). This stuff is
called "névé," and it normally forms each
year from any snow that falls and persists throughout the
winter. So, you find this old snow in lots of places that
don't have glaciers.
![[ névé, open2.net ]](http://www.open2.net/open2static/source/file/root/14/23/58841/snow_stages_b.jpg)
![[ névé, open2.net ]](http://www.open2.net/open2static/source/file/root/14/23/58841/snow_stages_c.jpg)
![[ névé, open2.net ]](http://www.open2.net/open2static/source/file/root/14/23/58841/snow_stages_d.jpg)
iii. If the névé survives the entire ablation
season, packing down and becoming blunter all the while, it
becomes "firn." Each year's firn is packed down more and
more tightly by the layers of firn forming above it, until
most of the air is pressed out of it.
![[ firn, open2.net ]](http://www.open2.net/open2static/source/file/root/14/23/58841/snow_stages_e.jpg)
![[ firn, open2.net ]](http://upload.wikimedia.org/wikipedia/commons/thumb/a/ac/Firn_from_South_Cascade_Glacier.jpg/180px-Firn_from_South_Cascade_Glacier.jpg)
iv. At this point, with densities getting above 850 km/cubic
meter, the firn becomes true glacier ice, a process that
may take from 25 to 100 years. The ice continues to become
denser through time as long as it exists in the glacier.
v. You can often see the separate layers of ice formed by the
annual accumlation and ablation cycle inside crevasses or
great cracks in the ice (which are extremely hazardous, by
the way, because they're so hard to see until you fall in).
![[ scientist sampling glacier layers, Taku
Glacier, Alaska, USGS image, converted from .gif to .png by Wikipedia ]](http://upload.wikimedia.org/wikipedia/en/thumb/e/e9/Taku_glacier_firn_ice_sampling.png/180px-Taku_glacier_firn_ice_sampling.png)
b. These ice accumulations begin to move and become true glaciers,
agents of erosion, transportation, and deposition, once they
become thick enough for gravity to press down on them so hard
that they begin to flow outward or downward away from that
pressure.
i. In other words, the downward stress of gravity acting on
the ice mass exceeds the shear strength (resistance to
differential lateral flow) of the ice.
ii. This exceedence causes plastic deformation, or squashing
outward and downward.
iii. For alpine glaciers, this usually occurs once the ice mass
exceeds about 20 m in thickness.
iv. This flow is outward in all directions (some of it is even
upward on the upper slopes of the mountainside just above
the glacier!), but the great preponderance of the flow will
be downward for an alpine glacier, as slope angle biases
the response of the ice mass to gravity.
c. The ice moves forward through its own internal plastic
deformation and through basal sliding.
i. Basal sliding is movement of the lower part of the glacier
as basal shear stress exceeds the resistance of the contact
between ice and rock.
ii. Basal sliding is facilitated by readily deformable earth
materials and by a glacier having a relatively warm base.
iii. If the temperatures at the bottom of the ice are close
enough to the melting point, meltwater may form below the
ice to lubricate its flow.
iv. Basal sliding can facilitate glacier motion up to 50 m/day!
d. Once the ice begins to flow, it will develop internal zones that
move at different rates of speed.
i. The flow is generally slowest along the bottom of the
glacier, due to the frictional resistance of contact with
the underlying rock.
![[ relative speed of ice movement with elevation
in a glacier, physicalgeography.net ]](http://www.physicalgeography.net/fundamentals/images/glacier_vert_profile.JPG)
ii. Flow is also slower along the sides of a confined glacier
for the same reason.
![[ relative speed of ice movement with elevation
in a glacier, physicalgeography.net ]](http://www.physicalgeography.net/fundamentals/images/glacier_hor_profile2.jpg)
iii. A glacier's middle sections flow fastest, especially near
the top surface, because there is no friction from the
ground to impede its movement and the ice molecules can
shear over other ice molecules.
iv. Extending flow develops when the internal flow lines in the
glacier spread out a bit, perhaps as a valley becomes less
confining, as the glacier spreads out on a piedmont, or
where the ice starts to "fall" down a steeper part of a
descending slope.
a. There is rotational movement at the top of a
concavity, produced by tension, resulting
in extending flow. This zone of extending flow is
called an "icefall," kind of like a waterfall!
b. Tensional forces cause ice failure here, so you often
see huge chunks of jumbled ice blocks marking this area.
![[ three icefalls, Tom Lowell, on National Snow
and Ice Data Center glossary site ]](http://nsidc.org/glossary/images/icefall.jpg)
v. Compressive flow forms wherever the flow lines of the ice
are brought closer together by "pinching" as a valley
narrows or wherever the slope of the landscape becomes
shallower (or wherever there is a small rise on an
otherwise descending slope). This is often seen just
downglacier from an icefall.
a. These slope variations or concavities in slope create
rotational flow at their upper and lower ends, with
compressive flow developing at the lower end of the
concavity where the ice tends to pile up.
b. The ice typically develops a bumpy, stepped appearance
here, called ogives (oh, jives). These look like arc-
shaped steps, with the center bulging downglacier.
c. There is often a train of them below an icefall.
![[ ogive train below an icefall, Juno Icefield,
Alaska, National Snow and Ice Data Center ]](http://nsidc.org/glossary/images/ogives.jpg)
vi. Where the ice is free of compression and extension, and ice
flow lines are moving parallel with themselves, any shear
stress may cause foliation. This is a deformation of the
ice in lines and planes parallel to the direction of flow,
which form along shear planes separating ice flows moving
at somewhat different speeds.
![[ glacier snout, showing foliation from shear,
geography-site.co.uk ]](http://www.geography-site.co.uk/pages/physical/glaciers/images/snout.jpg)
e. These varying rates of flow within the glacier exert tremendous
stresses on it from tension, compression, and shear forces. The
result can be ice failure in places, with cracks and fissures
and eventually great "crevasses" forming in the ice.
i. Crevasses are most commonly seen toward the "snout" or
outward limit of a glacier lobe, due to the tensional
stress there produced by divergent or extending flow and
because of the age of the ice and its history of repeated
failure.
ii. Because of the different rates of flow in the ice, however,
the crevasses themselves are pulled out of alignment,
forming lunar crescent shapes when seen from above. The
horns of the crescent point toward the source of the
glacier, away from the direction of flow.
iii. Crevasses are very serious hazards to anyone hiking up onto
a glacier. They are pretty much invisible until you fall
into them,
a. They are often hidden by a fresh snowfall or rock debris.
b. You may not see them, because you're a bit snowblind
from the full-spectrum reflection of sunlight from the
snow and ice.
c. And on cloudy days, there is less contrast to make out
these openings in the ice.
![[ crevasse in Antarctica, with top covered by
snow, National Science Foundation ]](http://www.nsf.gov/news/mmg/media/images/crevass_f.jpg)
![[ glacial crevasses hidden by snow, make-it-
real.net ]](http://www.make-it-
real.net/media/facts_crevasse1.jpg)
![[ crevasse in Antarctica, Wikipedia ]](http://upload.wikimedia.org/wikipedia/en/b/b0/Crevasse1.jpg)
![[ crevasse in Gorner Glacier, Switzerland,
Wikipedia ]](http://upload.wikimedia.org/wikipedia/commons/thumb/7/77/Crevasse.arp.500pix.jpg/403px-Crevasse.arp.500pix.jpg)
f. Glacier mass budget is a concept to help in understanding the
behavior of glaciers.
i. There are three components to glacier mass budget:
a. Accumulation of snow on the upper glacier, which has to
do with the amount and type of precipitation falling on
the source area, which relate to the absolute humidity
in the air, the temperature of the air, the slope on
which the ice accumulates, and winds (winds can scour
snow from a slope and prevent its accumulation).
b. Forward movement of the glacier and
c. Ablation of the lower glacier through melting, calving,
and even sublimation. Ablation is governed by air
temperature, reflectiveness of the snout's surface
(whether it's covered with insolation-absorbing debris),
type of precipitation in the snout area, wind speeds. Of
these, temperature is the most important.
ii. If all three are equal, then the glacier has gained and
pushed ahead an amount of ice equal to the amount lost
through ablation.
iii. If more ice is accumulated than ablates, then the glacier
grows, and its snout advances: Sustained advances in most
glaciers of the world mark ice ages.
iv. If more ice ablates at the edge of the glacier than
accumulates in its source, the snout retreats. Throughout
the process of retreat, ice continues to move downward and
outward, away from the source: It's just that it ablates
faster than it accumulates and pushes ahead. In other
words, glaciers don't retreat by shifting into reverse
gear!
v. So, while the mass budget is equal to net accumulation and
net loss (with continuing forward movement throughout), the
rate of flow is pretty complex because of the time lag
between one season's accumulation and the corresponding
movement of the glacier.
a. It takes decades for snowfall to evolve into glacial
ice.
b. Similarly, it takes decades for a large glacier to
respond to any one year's net accumulation.
c. As a result, it is not uncommon for glacier behavior to
be out of phase with current climatic trends.
d. Sometimes glaciers engage in surges or pretty sudden
extensions (at maybe 10 or 20 or even 50 m per
day! This may reflect a concentrated input of
gravitational energy, such as a really snowy winter or
run of snowy winters, many decades before, or the
lubrication of meltwater underneath the glacier as
temperatures from a long-ago hot spell diffuse there.
vi. That said, although some modern glaciers are still
advancing, the vast majority of glaciers are retreating at
the present time. So, their mass balances are negative.
This could be because:
a. Less snow is falling and accumulating over the last
several decades or centuries or
b. Temperatures have been warming in that timeframe or
c. Both
vii. This could reflect the warming of the planet's atmospheric
temperature with the ending of the Little Ice Age of the
1700s and early 1800s (when a number of glaciers made
strong advances and/or it could reflect human activity
adding greenhouse gasses to the atmosphere.
5. Glacial erosion mechanisms.
a. Glacial ice by itself is not likely to erode most bedrock,
because the bedrock has greater shear strength than the yield
stress of the ice. That is, the ice will fail a lot sooner than
the rock will. Yet, glaciers are undoubtedly one of the
greatest erosive forces sculpting the high latitude and high
elevation parts of the land. Glaciers accomplish this seemingly
contradictory trick through picking up rock materials and then
using them to abrade the surfaces over which they pass.
b. Plucking occurs when glaciers pick up and incorporate rock
fragments on their underside.
i. Bedrock usually is jointed and cracked.
ii. Basal sliding generates friction, which often melts some of
the ice on the bottom of the glacier.
iii. This water flows into those cracks and joints.
iv. This water is also under tremendous pressure from the
weight of the ice above, so it is injected with enough
force to exert an upward pressure on the rock materials it
flows into, essentially jacking them upwards, where they
can be progressively lodged into the ice itself as the
water refreezes whenever the glacier pauses.
v. Plucking often creates a pocked and pitted surface where
rock chunks have been lifted up out of the bed.
c. Scouring occurs when glaciers use this material to abrade the
land surface. Some of the material is enbedded within the ice
and some of it is carried along under the ice, meaning the
glacier sort of rolls along on the material lodged under it.
i. Abrasion lasts as long as the rock material survives.
ii. As time goes on, each rock chunk is worn down in size and
is able to produce only smaller and smaller scratches on
the underlying rock surface.
iii. Eventually, these rock materials are worn down to a clay-
sized powder which makes glacial meltwater look kind of
cloudy or milky. This fine rock material is called
"glacial flour," and the cloudy meltwater is called
"glacial milk."
d. Alpine or valley glaciers often erode through undermining the
slopes above them, which results in a pile of unsorted debris on
their surfaces, which is carried along with the ice and
eventually deposited at the glacial snout.
e. Some of the surface debris is actually material that originated
in the bottom of the glacier but was carried up along
deformation planes in the ice, as by the rotational flow that
produces ogives.
6. Landscape features produced by glacial erosion vary depending on
whether we're talking about the smaller alpine, valley, or piedmont
glaciers or the huge ice sheet glaciers.
a. Smaller glaciers.
i. Striations are grooves or scour lines worn into bedrock by
rocks entrained in the ice passing over it. They typically
become smaller in width and depth as you move downward in
the direction the ice once flowed, which makes sense, given
that this scouring will eventually wear the rock fragment
into powder.
![[ striations, USGS ]](http://education.usgs.gov/schoolyard/IMAGES/GlacialStriations2.jpg)
ii. A plucked landscape is pitted and you often see the rock
clasts that were in the process of being removed when the
ice ablated and the ice age ended.
![[ plucked surface in Sierra Nevada, C.J.
Woltemade, Earth Science, Shippenburg State ]](http://www.ship.edu/~cjwolt/geology/slides/jpg/gl09.jpg)
iii. Glacial polish is a smoothly polished surface that formed
on resistant igneous rock (e.g., granite) that was scoured
to nearly the point of being shiny by glacial flour.
![[ glacial polish on basalt, Minnesota, Winona
State University Geosciences ]](http://www.winona.edu/geology/MRW/mrwimages/striatedbasaltWI.jpg)
iv. Glacial pavement is a rock surface from which all soil was
carried away by ice. It may show striations and polish,
and there may be glacial erratics, or rocks stranded when
the ice melted out from under it.
![[ glacial pavement on basalt
columns, Yosemite, Sierra Club ]](http://www.sierraclub.org/john_muir_exhibit/writings/our_national_parks/graphics/4.jpg)
v. Roche moutonnée or "woolly rock" or "sheep-shaped
rock" is a rock knob with one side scoured or even polished
by materials compressed against against it and the other
side plucked by the extending flow of ice pulling away from
it. The scoured side faces the direction the ice came from
and has a gentle slope, and the plucked side faces the
direction the ice was flowing towards and features a
steeper slope.
![[ roche moutonnee diagram, G. Hayes, Yosemite
Community College ]](http://virtual.yosemite.cc.ca.us/ghayes/Tuolumne_Meadows_Field_Trip_files/image018.jpg)
![[ roche moutonnee, Judson Ahern, Oklahoma
University ]](http://dynamic.ou.edu/notes/glaciers/continental/roche_moutonnee,ice_movement_rt_to_lt,me.jpg)
vi. Cirques are circular or semi-circular gouges or concavities
high on a mountainside produced by a cirque glacier.
a. The head of the glacier will undermine the top of the
slope by the formation of a crevasse or "bergschrund"
each summer when there is summer melting and the glacier
pulls away from the upper wall of the slope. Then all
sorts of debris and meltwater falls into the opening and
refreezes there, squashing into the bedrock and
undermining it.
b. So what's left after the ice melts is this circular or
semi-circular depression in the slope, which may contain
a small lake, which is called a "tarn."
![[ tarn in newly deglaciated landscape, Chugach
Mountains, Alaska, by Bruce Molnia, USGS ]](http://www.calacademy.org/science_now/images/arcticmelt1.jpg)
vii. An arête is the sharp, toothy ridge produced when
adjacent cirques cut back into one another.
viii. A horn is the sharp, spire-like peak that's left of a
mountain when cirques have undermined much of the highest
part of the mountain. The spire has arêtes radiating
out from it, bordering the cirques. In this photograph,
you can see a horn with two spires, two cirques, and three
arêtes.
![[ horn, cirques, aretes in Juneau Icefield;
Scott McGee ]](http://crevassezone.org/Photos/Graphics/2390S-(C-19-peaks).jpg)
ix. U-shaped valleys are created when an alpine glacier flows
down a pre-existing stream valley and gouges at its sides
and bottom and undermines its sides until the V-shaped
cross-section usually associated with mountain streams
becomes U-shaped.
a. Hanging valleys are small U-shaped valleys created when
a tributary glacier merges and flows directly onto a
larger glacier. The tributary glacier, with its smaller
mass and erosional ability, creates a small U-shaped
valley that ends abruptly over the edge of the much
larger U-shaped valley created by the larger valley
glacier. The larger valley glacier was able to excavate
its valley much more effectively than the small
tributary glacier due to its much greater weight. As a
result, the larger valley suddenly cuts off the smaller
valley, which is left suspended high over the main
valley. Once the ice melts, the streams that flow in
these tributary valleys end in spectacular water falls,
like you see in Yosemite Valley.
![[ diagram of hanging valleys over main U-
shaped valley, Fisheries and Oceans Canada ]](http://www.glf.dfo-mpo.gc.ca/sci-sci/bysea-enmer/images/img_after_glaciation.jpg)
b. Fjords are U-shaped valleys produced by tidewater
glaciers. Since the glacier reached the sea at the end
of these valleys, the ending of the ice age and the
associated rise in sea levels allowed the sea to invade
these valley to form fjords. You see these a lot on the
coasts of Alaska, British Columbia, Norway, New Zealand,
and Chile.
![[ Norwegian fjord coast, Sandlund blog ]](http://www.sandlund.net/voices/archive/fjord.jpg)
b. The huge continental-scale glaciers have such tremendous erosive
power that they tend to obliterate much of the underlying
landscape, making the erosional features associated with them
rather indistinct.
i. Glacial pavement, indeed vast plains of exposed bedrock or
bedrock covered with the thinnest and most skeletal soils
that have managed to develop over the last 10-15 thousand
years. An example would be the Laurentian Shield of
eastern Canada, which is a huge craton worn smooth by the
Laurentian ice sheet.
ii. Deranged drainage, which means that the varying weight of
the great ice sheets, coupled with variations in the
underlying bedrock and haphazard deposition as the ice
melted, created irregular patterns of minor highs and lows
on the surface. After the ice melts, the resulting low
spots drain poorly and fill with lakes and wetlands and the
streams that do drain them often take the "scenic route" in
getting from Point A to Point B. The stream system simply
hasn't had enough time to organize the drainage into an
orderly pattern leading water from higher spots to lower
base level. Now, you know why Wisconsin is called the
"Land of 10,000 Lakes"!
![[ map of deranged drainage, McGillivray Falls
area, Whiteshell Provincial Park, Manitoba, Canada, by
Manitoba Conservation ]](http://www.gov.mb.ca/conservation/parks/popular_parks/mcgillivray_falls/map1.jpg)
iii. Large lakes often form where a continental ice sheet flowed
off a crystalline shield or craton onto weaker sedimentary
rock beds. Examples are the Great Lakes and Finger Lakes of
the northern United States and southeastern Canada, which
actually continue in the system of large lakes in central
Canada (e.g., Lake Winnipeg in Manitoba, Great Slave Lake
and Great Bear Lake in the Northwest Territories).
iv. Nunataks are mountains sticking out of the ice. When the
ice melts, they will be grossly eroded on their steep
sides. Nunataks are pretty much the only source of rock
debris that can be found on the surface of the kilometers-
thick continental ice sheets.
![[ nunatak, Antarctica, D. Fabel, Glasgow
University ]](http://web.ges.gla.ac.uk/~dfabel/GU_images/NVLprojectsml.jpg)
7. Transportation by glaciers.
a. Glaciers incorporate plucked material along their bottoms and
sides as lodgement till (lodged under the glacier).
b. This material may be brought up to the surface if there are
deformation planes or crevasses that reach to the bottom of the
glacier.
c. Material carried on the surface of the glacier (from the
undermining of the slopes that confine a glacier or from
nunataks or from dust blown onto the surface of the glacier):
Alpine glaciers are much cruddier than continental ice sheets
because they have so many more sources of debris available to
them.
i. Some of this surface debris forms lines along the sides of
the glacier.
ii. Where two glaciers come together, these lateral lines of
debris often join into a single streak running down the
middle of the glacier.
d. Surface materials may fall into the interior of a glacier along
crevasses (including hapless hikers!).
8. Deposition by glaciers.
a. Glaciers push a lot of material within and atop the ice to the
snout.
i. If the ice snout is on a land surface, the debris is
unceremoniously dumped as the ice melts out from under it.
This forms a heap of unsorted debris at the outer edge of
the ice. These heaps will form wherever the edge of the
ice is stable for a long time.
ii. If the glacier terminates in the sea, the ice will continue
to spread out on the surface of the sea well beyond its
"grounding line" (where the ice loses contact with the
ground surface, at a depth approximately 90 percent the
thickness of the ice). The ice sheet thins outward due to
heat flux up from the ocean water. The ice sheet is
buoyant, but the inevitable tension and compression due to
tides on its leading edge will lead to ice failure and the
calving off of icebergs -- which include not just the ice
but the rock debris on and in the ice.
iii. Some of the finest glacial flour will be blown off the
snout of the glacier, too.
b. In addition to straight ice deposition, there is also fluvial
deposition associated with glaciers. This is called
"glaciofluvial deposition."
i. Glaciers extending into temperate climate areas often
experience melting on their surfaces, which creates ponds
on the surface.
ii. Some of this water flows horizontally across the top of the
glacier just like a regular stream, and pours off the end
of the glacier's snout, where it deposits a texture-sorted
fan of debris, just like the alluvial fans deposited by
ordinary streams pouring out of canyons.
iii. Some drop vertically into the glacier along "moulins" or
crevasses.
iv. Some water is formed by frictional heating underneath the
glacier, which I mentioned earlier in connection with
plucking. The water inside the ice is often under
tremendous pressure and this alone can make it pretty
erosive. Some of the water under the glacier forms
channels of its own and, like any stream, will deposit rock
material in the stream beds.
9. Landscape features produced by glacial deposition.
a. Terminal moraines are the heaps of unsorted debris deposited on
the land surface at the outermost extent of a glacier's farthest
advance. The ridge to the upper right near the road is a
terminal moraine, the ice having come up from the lower left of
the image.
![[ moraines, Sedgwick, ME, Maine Department of
Conservation ]](http://web.archive.org/web/19970728210304/http://www.state.me.us/doc/nrimc/pubedinf/photogal/surfical/airmor.gif)
b. Recessional moraines develop as the glacier experiences negative
mass balance and begins to melt back. Since the process of
retreat is very uneven and may even feature re-advances of the
ice, the moraines often have an opportunity to pile up in
ridges, just like the terminal moraine. You can see a few of
them in the image above.
c. Ground moraine also forms during the process of melting back,
particularly during relatively even phases in the melt back. It
consists of the till carried below the glacier, which is often
reduced to powder (clay). In among the clay will be larger
rocks, which were dropped before the glacier had a chance to
pulverize them completely. I've heard ground moraine (as in
ground-up) described as "boulder-studded clay."
![[ ground moraine, Newfoundland, Geological Survey of NF
and LB ]](http://web.archive.org/web/20020702160556/http://www.geosurv.gov.nf.ca/images/minjpg/67_2.GIF)
d. Lateral moraines mark the sides of a confined glacier. They are
derived from the debris undermined from the sides of the
mountains confining them. Lateral moraines join up with the
terminal moraines more or less at right angles to form chevron-
shaped heaps at their intersection.
![[ lateral moraine, Baffin Island, Canada, Geological
Survey of Canada ]](http://www.uwsp.edu/gEo/faculty/ritter/images/lithosphere/glacial/moraines_v_glacier_Baffin_GSC_18val_annotated_small.jpg)
e. Medial moraines are made of the debris carried atop the middle
of a valley glacier when two tributary glaciers came together
and their lateral loads linked up. Like the lateral moraines,
they join up with the terminal moraines more or less at right
angles to form chevrons of debris.
![[ medial moraine, Southeast Alaska, Sharon Johnson,
Geoimages, U.C. Berkeley ]](http://geoimages.berkeley.edu/Geoimages/Johnson/Images/Large/CD2/035.jpg)
f. Erratics are rocks or boulders that had been carried along on
the top of the glacier but which were dumped when the ice
ablated out from under them. They often are made of material
quite foreign to the area they were dropped, which tells you
they rode quite a long way.
![[ large erratic, Southeast Alaska, Sharon Johnson,
Geoimages, U.C. Berkeley ]](http://geoimages.berkeley.edu/Geoimages/Johnson/Images/Large/CD2/037.jpg)
g. Perched rocks are erratics stranded on a precarious perch.
![[ perched boulder, New England, Dan Boudillion, New
England Antiquities Research Association ]](http://www.neara.org/Boudillion/P07.jpg)
h. Here's a shot of a moraine at the snout of a surging glacier,
which is actually in the process of bulldozing some trees,
caught in the act by Scott McGee, who runs the crevassezone.org web site!
![[ surging glacier's moraine pushing over trees, Scott
McGee ]](http://crevassezone.org/Photos/Graphics/3487S-(Taku-advance).jpg)
i. Drumlins are mounds of debris formed from deformed sheets or
beds of lodgement till. They typically are teardrop-shaped and
run parallel to the ice flow.
![[ drumlin, Provincial Museum of Alberta, Canada ]](http://www.pma.edmonton.ab.ca/vpub/geology/images/cd33022.gif)
10. Fluvioglacial depositional features.
a. Kettle lakes are depressions that were occupied by chunks of ice
during the process of recession and then buried or partly buried
by fluvioglacial debris. When the ice chunks finally do melt,
the exposed depression is filled by lakes.
b. Kames are conical fans of texture-sorted material created by a
stream flowing off the top of a continental glacier and over
moraines. They can occur in lines during the process of
recession and so form terraces of fused kames. They can also
form from the debris trapped in crevasses toward the glacier's
snout, which, when exposed by recession, then collapse into
small hills and ridges.
![[ kame and kettle topography, William Locke, Montana
State University, Bozeman ]](http://gemini.oscs.montana.edu/~geol445/hyperglac/meltwater1/kettles.jpg)
c. Related to kames but on the alpine scale are valley trains,
which are the reworked and texture-sorted debris created by a
stream flowing off the top of the glacier and over the moraine
at its snout and down the valley below the glacier's terminus.
They are analogous to alluvial fans produced by regular mountain
streams flowing out onto a flatter valley floor.
d. An outwash plain is a larger texture-sorted feature fed by the
outwash from several supraglacial streams (kind of like a
bajada).
e. Eskers are the bed deposits of streams that developed under a
glacier. The result is a
winding ridge of bed deposits built up over the surrounding
ground moraine surface when the ice melts back.
![[ Bedshiel Esker, Southern Upland Partnership,
Scotland ]](http://www.sup.org.uk/images/bedshiel_esker.jpg)
![[ T. Tierney,
Project ADEPT, piru.alexandria.ucsb.edu ]](http://piru.alexandria.ucsb.edu/collections/geography3b/misc/esker.jpg)
11. Glacio-æolian erosion and deposition.
a. Glaciers are often associated with strong winds.
b. These will often deflate or pick up glacial flour -- clay sized
clasts -- or silt-sized particles.
c. These winds will then carry the fine material far from the
glaciers, depositing it elsewhere to build up thick beds of
something called "loess."
d. Loess forms a very crumbly and high quality soil, much desired
for agricultural purposes. There is a lot of it in the American
Midwest and in China.
![[ loess blowing off a glacier, Geography 3b
Collection, Project ADEPT, piru.alexandria.ucsb.edu ]](http://piru.alexandria.ucsb.edu/collections/geography3b/misc/loess2.jpg)
![[ loess deposit, Tadjikistan, Project Changes, M. Telfer ]](http://changes.ouce.ox.ac.uk/images/Tajik-Loess-small.jpg)
12. Glacial trends today.
a. Because of the lag between snow accumulation and glacial motion,
depending on local climates, we can find glaciers that are
surging or advancing quickly and glaciers that are retreating in
the world today.
b. The Taku Glacier up in Alaska is advancing (remember the picture
of it pushing over some trees?), which is unique among the other
Juneau Icefield glaciers. Arctic glaciers, in general, are
retreating but more slowly than is the case in the rest of the
world.
c. Most places, however, glaciers are in rapid retreat:
i. The glaciers in the Alps have lost about 30-40 percent of
the area they cover and about 50 percent of their volume
since 1850.
ii. The glaciers in New Zealand have lost about 25 percent of
their area in the last 100 years.
iii. Glaciers in Central Asia have been declining since the
1950s.
iv. Glaciers in East Africa on Mt. Kenya and Mt. Kilimanjaro
have lost about 60 percent of their area over the last
century and are doing so at a faster rate recently.
v. Glaciers in the Andes are now in accelerated retreat, too.
d. The question is whether the retreating glaciers are responding
to the world-wide recovery from the Little Ice Age of the 1700s
or to human-induced increases in carbon dioxide or both.
Whether or not they are responding to human-induced climate
change, humans may need to reduce greenhouse gas production if
for no other reason than to offset the warming associated with
the end of the Little Ice Age. Given the lag in glacial
response to temperature and humidity inputs, however, we may
well see significant glacial melting over the course of our
lifetimes, with a consequent increase in global sea level. A
rise in sea level is very problematic, given that the world's
population tends to concentrate in low lying areas not far from
the coast. Unfortunately, the earth sciences do not yet have
enough data to answer the critical question of the meaning and
the rate of glacial change. Perhaps some of you might be
inspired to take on the training in the various earth sciences
necessary to put more trained people on the frontlines of
answering this question?
![[ North American coastlines today, 18,000 bp, and if the polar ice
caps melted, Judson Ahern, Oklahoma University ]](http://dynamic.ou.edu/notes/glaciers/coastlines.jpg)
Document and © maintained by Dr.
Rodrigue
First placed on web: 05/13/01
Last revised: 07/09/07