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Transcript 
Chapter 12
The Proterozoic Eon
of Precambrian Time
Guiding Questions
• How did mountains form in Proterozoic time?
• What global climatic and biological changes
took place in the Proterozoic Eon?
• What evidence is there that oxygen began to
build up in the atmosphere about 2.3 million
years ago?
• Why do some scientists use the label “snowball
Earth” to describe out planet during part of the
Neoproterozoic time?
• What did continental suturing accomplish on a
global scale during Neoprotozoic time?
Proterozoic Eon
• Precambrian
– Proterozoic
• 2.5 Billion to ~ 0.6
Billion years ago
– Archean
Proterozoic Orogeny
• Formation of large
cratons
• By ~1 Billion years
ago, modern style
orogeny
• Wopmay
• 2 Billion years
• Slave Province
– Ancient fold
and thrust belt
Proterozoic
Orogeny
• Thick deposit of quartz
sandstone
• Carbonate platform
• Transitional mudstones
• Flysch deposits
• Turbidites then
mudcracks and
stromatolites
• Molasse deposition
Proterozoic Orogeny
• Carbonate platform
– Cyclic deposits
indicated
progradation of
tidal flats across
lagoon
– Laminated dolomite
forms base
– Oolites or
stromatolites are at
top
Proterozoic Events
• Widespread glaciation
– Gowganda deposits
– 2.3 Ga
• Stromatolites
– Proliferate
– Diverse shapes 1.2
Billion years ago
• Early Eukaryotes
Evolution of Eukaryotes
• Union of 2 prokaryotic
cells
– Mitochondrian
• Allow cells to derive energy
from their food by respiration
• Evolved from 1 prokaryotic
cell
– Chloroplast
• Site of photosynthesis
• Protozoan consumed, retained
cyanobacterial cell
Algae
• Multicellular
protists
• Algal ribbons
wound into loose
coils
– 2.1 Billion years
ago
Algae
• Prokaryotic forms
– Gunflint flora 2 Billion years ago
– Lake Superior
• Acritarchs
– Multicellular forms abundant after 2 Billion years
Proterozoic Life
• Complex organisms
can be identified
from trace fossils
– None present until
about 570 Million
years ago
• Belt Supergroup,
Montana
• 1.3 Billion years
ago
Proterozoic Life
• Trace fossils
provide evidence
for past life in
Neoproterozoic
• Increasingly
complex and varied
Proterozoic Life
• Non-skeletal fossils
– Similar to Cnidaria
– Imprints of softbodied organisms
– < 570 M years ago
• Ediacarian fauna
– Lived before
predators
– Some similar to
modern forms
Proterozoic Life
• Possible arthropod fossils
Proterozoic Life
• Skeletal fossils
– Vase-shaped and
tubular
– Small size
• Timing may be
related to
glaciations
Proterozoic
Continents
• Continental accretion
– Microplate accreted to
continent
– Orogenic stabilization
• Welds sediment to crust
• Thickens crust, hardens
unconsolidated sediments
• Remobilization
– Alter character of preexisting rocks
– Reset radiometric clocks
Proterozoic Continents
• Canadian Shield
– Includes Northern
U.S.
• Laurentia grew by
accretion during
Proterozoic
Proterozoic Continents
• 1.95–1.85 Billion years
ago
– Superior Province is
largest
• 1.9–1.8 Billion years
old rock unit
– Separates Superior
Province from Wyoming
and Hearne provinces
• 1.8–1.6 Billion years
ago
– Exposed in Southern
Wyoming to Northern
Mexico
Proterozoic Continents
• Wyoming Province
– Archean terrane
exposed in Wyoming
and Black Hills
• Laurentia was
probably attached to
Australia, Antarctica
and Siberia
Proterozoic Continents
• Failed rift 1.2–1.0
Billion years ago
– Volcanic belt through
midwest
– Keweenawan basalts
• Grenville Orogeny 1.1
Billion years ago
– Accretionary event
• Added eastern belt
– Exposed in Canada,
Adirondacks, Blue
Ridge, Llano (TX)
uplift
Proterozoic Continents
• Keweenawan
basalts
– Copper ore
– Form midcontinent gravity
high
Proterozoic Continents
• Rodinia
– Supercontinent
• United Laurentia to
other land masses
• Full assembled 1
Billion years ago
– Broke up 0.8–0.7
Billion years ago
• Created Pacific
Ocean
• Created failed rifts
in Western
Laurentia
Proterozoic Continents
• Belt Supergroup
– 0.9–1.5 Billion years ago
– Thick sequence of sediments formed in failed rift
– Accumulated in shallow water during rapid subsidence
Banded Iron Formations
• Stopped forming 1.9
Billion years ago
– Chert contaminated
by iron
• Red or brown color
– Alternate with ironrich layers
(magnetite)
• Oxygen-poor ocean
waters
• Iron was not
oxidized
Red Beds
• Never found in
terranes older than
2 Billion years
Snowball Earth
• Neoproterozoic glacial deposits
Snowball
Earth
• Light carbon
isotopes
Snowball Earth
Snowball Earth
• Growth of
stromatolites over
columnar crystals
of aragonite
Snowball Earth
• Evidence for Marinoan ice age in Morocco
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