the Proterozoic Eon alone,

1
The Length of the Proterozoic

• the Proterozoic Eon alone,
• at 1.955 billion years long,
• accounts for 42.5 of all geologic time
• yet we review this long episode of Earth and life
  history in a single section

2
The Phanerozoic

• Yet the Phanerozoic,
• consisting of
• Paleozoic,
• Mesozoic,
• Cenozoic eras,
• lasted a comparatively brief 545 million years
• is the subject of the rest of the course

3
The Proterozoic EonTop Ten Significant Events

• Plate tectonics occurred similar to modern rates
• Accretion at continental boundaries
• Assembly of Laurentia and two super continents
• Widespread sandstone, carbonate, shale deposits
  (continental shelf deposits)
• Extensive continental glaciation
• Mid-continent rift formed in North America
• Widespread occurrence of stromatolites
• Formation of banded iron and other mineral
  resources (gold, copper, platinum, nickel)
• Free oxygen in atmosphere
• Evolution of eukaryotic cells

4
Style of Crustal Evolution

• Archean crust-forming processes generated
• granite-gneiss complexes
• and greenstone belts
• that were shaped into cratons
• During the Proterozoic, these formed at a
  considerably reduced rate and cooler temperatures

5
Contrasting Metamorphism

• Many Archean rocks have been metamorphosed,
• However, vast exposures of Proterozoic rocks
• show little or no effects of metamorphism,
• and in many areas they are separated
• from Archean rocks by a profound unconformity

6
Evolution of Proterozoic Continents

• Archean cratons assembled during collisions of
  island arcs and minicontinents,
• providing the center of todays continents.
• Proterozoic crust accreted, at edges forming much
  larger landmasses
• Proterozoic accretion at craton margins
• probably took place more rapidly than today
• Earth possessed more radiogenic heat,
• but the process continues even now

7
Proterozoic Greenstone Belts

• They were not as common after the Archean,
• near absence of ultramafic rocks
• WHY would this happen?

8
Focus on Laurentia

• Our focus here is on the geologic evolution of
  Laurentia,
• a large landmass that consisted of what is now
• North America,
• Greenland,
• parts of northwestern Scotland,
• and perhaps some of the Baltic shield of
  Scandinavia

9
Early Proterozoic History of Laurentia

• Laurentia originated 2.0 billion years ago
• collisions called orogens
• formed linear or arcuate deformation belts
• in which many of the rocks have been
• metamorphosed
• and intruded by magma
• thus forming plutons, especially batholiths

10
Proterozoic Evolution of Laurentia

• Archean cratons were sutured
• along deformation belts called orogens,
• By 1.8 billion years ago,
• much of what is now Greenland, central Canada,
  and the north-central United States existed

• Laurentia grew along its southern margin
• by accretion

11
What is the evidence?Craton-Forming Processes

• Recorded in rocks
• In northwestern Canada
• where the Slave and Rae cratons collided

12
Craton-Forming Processes

• the Trans Hudson orogen
• in Canada and the United States,
• where the Superior, Hearne, and Wyoming cratons
• were sutured
• The southern margin of Laurentia
• is the site of the Penokian orogen

13
Wilson Cycle

• Rocks of the Wopmay orogen
• in northwestern Canada are important
• because they record the Wilson cycle
• opening and closing of an ocean basin
• A complete Wilson cycle,
• named for the Canadian geologist J. Tuzo Wilson,
• involves
• fragmentation of a continent (rifting)
• opening of an ocean basin
• followed by closing of an ocean basin,
• and finally reassembly of the continent

14
Wopmay Orogen

• Some of the rocks in Wopmay orogen
• are sandstone-carbonate-shale assemblages,
• a suite of rocks typical of passive continental
  margins
• that first become widespread during the
  Proterozoic

15
Early Proterozoic Rocks in Great Lakes Region
Evidence of continental shelf

• Early Proterozoic sandstone-carbonate-shale
  assemblages are widespread near the Great Lakes

16
Where? N. MichiganOutcrop of Sturgeon Quartzite

• The sandstones have a variety of sedimentary
  structures
• such as
• ripple marks
• and cross-beds
• Northern Michigan

17
Outcrop of Kona Dolomitewarm shallow marine

• Some of the carbonate rocks, now mostly
  dolostone,
• such as the Kona Dolomite,
• contain abundant bulbous structures known as
  stromatolites
• NorthernMichigan

18
Penokean Orogen

• These rocks of northern Michigan
• have been only moderately deformed
• and are now part of the Penokean orogen

19
Southern Margin Accretion

• Laurentia grew along its southern margin
• by accretion of the Central Plains, Yavapai, and
  Mazatzal orogens

• Also notice that the Midcontinental Rift
• had formed in the Great Lakes region by this time

20
BIF, Red Beds, Glaciers

• This was also the time during which
• most of Earths banded iron formations (BIF)
• were deposited
• The first continental red beds
• sandstone and shale with oxidized iron
• were deposited about 1.8 billion years ago
• We will have more to say about BIF
• and red beds in the section on The Evolving
  Atmosphere
• In addition, some Early Proterozoic rocks
• provide excellent evidence for widespread
  glaciation

21
Proterozoic Igneous Activity

• These igneous rocks are exposed
• in eastern Canada, extend across Greenland,
• and are also found in the Baltic shield of
  Scandinavia

22
Igneous ActivityWhy? How do we know?

• However, the igneous rocks are deeply buried
• by younger rocks in most areas
• The origin of these
• are the subject of debate
• According to one hypothesis
• large-scale upwelling of magma
• beneath a Proterozoic supercontinent
• produced the rocks

23
Middle Proterozoic Orogeny and Rifting

• The only Middle Proterozoic event in Laurentia
• was the Grenville orogeny
• in the eastern part of the continent
• 1.3 to 1.0 billion years old
• Grenville rocks are well exposed
• in the present-day northern Appalachian Mountains
  
• as well as in eastern Canada, Greenland, and
  Scandinavia

24
Grenville Orogeny

• A final episode of Proterozoic accretion
• occurred during the Grenville orogeny

25
75 of North America

• By this final stage, about 75
• of present-day North America existed
• The remaining 25
• accreted along its margins,
• particularly its eastern and western margins,
• during the Phanerozoic Eon

26
Midcontinent Rift

• Grenville deformation in Laurentia
• was accompanied by the origin
• of the Midcontinent rift,
• a long narrow continental trough bounded by
  faults,
• extending from the Lake Superior basin southwest
  into Kansas,
• and a southeasterly branch extends through
  Michigan into Ohio
• It cuts through Archean and Early Proterozoic
  rocks
• and terminates in the east against rocks
• of the Grenville orogen

27
Location of the Midcontinent Rift

• Rocks filling the rift
• are exposed around Lake Superior
• but are deeply buried elsewhere

28
Midcontinental Rift

• Most of the rift is buried beneath younger rocks
• except in the Lake Superior region
• with various igneous and sedimentary rocks
  exposed
• The Evidence
• numerous overlapping basalt lava flows
• forming a volcanic pile several kilometers thick

29
Portage Lake Volcanics

• Michigan

30
Sedimentary Rocks

• Middle to Late Proterozoic sedimentary rocks
• are exceptionally well exposed
• in the northern Rocky Mountains
• of Montana and Alberta, Canada
• Glacier National Park

31
Proterozoic Rocks, Glacier NP

• Proterozoic sedimentary rocks
• in Glacier National Park, Montana
• The angular peaks, ridges and broad valleys
• were carved by Pleistocene and Recent glaciers

32
Proterozoic Mudrock

• Outcrop of red mudrock in Glacier National Park,
  Montana

33
Proterozoic Limestone

• Outcrop of limestone with stromatolites in
  Glacier National Park, Montana

34
Grand Canyon Super-group

• Proterozoic Sandstone of the Grand Canyon
  Super-group in the Grand Canyon Arizona

35
Proterozoic Supercontinents

• A supercontinent consists of all
• Or much of the present-day continents,
• so other than size it is the same as a continent
• The supercontinent Pangaea,
• existed MUCH LATER but few people are aware of
  earlier supercontinents

36
Early Supercontinents

• Rodinia
• assembled between 1.3 and 1.0 billion years ago
• and then began fragmenting (rifting apart) 750
  million years ago (THE Proterozoic ends at 545my
  ago)

37
Early Supercontinent

• Possible configuration
• of the Late Proterozoic supercontinent Rodinia
• before it began fragmenting about 750 million
  years ago

38

• Rodinia's separate pieces reassembled
• and formed another supercontinent
• Pannotia
• about 650 million years ago
• Fragmentation was underway again,
• about 550 million years ago,
• giving rise to the continental configuration
• that existed at the onset of the Phanerozoic Eon
  the Cambrian

39
Recognizing Glaciation

• How can we be sure that there were Proterozoic
  glaciers?
• the extensive geographic distribution
• of other conglomerates and tillites
• and their associated glacial features
• is distinctive,
• such as striated and polished bedrock

40
Proterozoic Glacial Evidence

• Bagganjarga Tillite in Norway
• Over bedrock

41
Geologists Convinced

• The occurrence of tillites
• in Michigan, Wyoming, and Quebec
• indicates that North America may have had
• an Early Proterozoic ice sheet centered southwest
  of Hudson Bay

42
Early Proterozoic Glaciers

• Deposits in North America
• indicate that Laurentia
• had an extensive ice sheet
• centered southwest of Hudson Bay

43
Late Proterozoic Glaciers

• The approximate distribution of Late Proterozoic
  glaciers

44

• Late Proterozoic glaciers
• seem to have been present even
• in near-equatorial areas!!
• Geologists have recently named this phenomenon
• SNOWBALL EARTH

45
The Evolving Atmosphere

• Archean little or no free oxygen
• the amount present
• at the beginning of the Proterozoic was probably
  no more than 1 of that present now
• Stromatolitesnot common until
• 2.3 billion years ago,
• that is, during the Early Proterozoic
• There is evidence of increasing oxygen.

46
Early Proterozoic Banded Iron Formation

• At this outcrop in Ishpeming, Michigan
• the rocks are alternating layers of
• red chert
• and silver-colorediron minerals

47
Banded Iron Formations (BIF)

• Banded iron formations (BIFs),
• consist of alternating layers of
• iron-rich minerals
• and chert
• about 92 of all BIFs
• formed during the interval
• from 2.5 to 2.0 billion years ago

48
BIFs and the Atmosphere

• How are these rocks related to the atmosphere?
• Their iron is in iron oxides, especially
• hematite (Fe2O3)
• and magnetite (Fe3O4)
• Iron combines with oxygen in an oxidizing
  atmosphere
• to from rustlike oxides
• that are not readily soluble in water
• If oxygen is absent in the atmosphere, though,
• iron easily dissolves
• so that large quantities accumulate in the
  world's oceans,
• which it undoubtedly did during the Archean

49
Formation of BIFs

• The Archean atmosphere was deficient in free
  oxygen
• so that little oxygen was dissolved in seawater
• However, as photosynthesizing organisms
• increased in abundance,
• as indicated by stromatolites,
• free oxygen,
• released as a metabolic waste product into the
  oceans,
• caused the precipitation of iron oxides along
  with silica
• and thus created BIFs

50
Formation of BIFs

• Depositional model for the origin of banded iron
  formation

51
Source of Iron and Silica

• A likely source of the iron and silica
• was submarine volcanism,
• similar to that now talking place
• at or near spreading ridges
• Huge quantities of dissolved minerals are
• also discharged at submarine hydrothermal vents
• In any case, the iron and silica
• combined with oxygen
• thus resulting in the precipitation
• of huge amounts of banded iron formation
• Precipitation continued until
• the iron in seawater was largely used up

52
Continental Red Beds

• Obviously continental red beds refers
• to red rocks on the continents,
• but more specifically it means red sandstone or
  shale
• colored by iron oxides,
• especially hematite (Fe2O3)

Red mudrock in Glacier National Park, Montana
53
Red Beds

• Red beds first appear
• in the geologic records about 1.8 billion years
  ago,
• increase in abundance throughout the rest of the
  Proterozoic,
• and are quite common in rocks of Phanerozoic age
• The onset of red bed deposition
• coincides with the introduction of free oxygen
• into the Proterozoic atmosphere
• However, the atmosphere at that time
• may have had only 1
• or perhaps 2 of present levels

54
Red Beds

• Is this percentage sufficient to account
• for oxidized iron in sediment?
• Probably not,
• but no ozone (O3) layer existed in the upper
  atmosphere
• before free oxygen (O2) was present
• As photosynthesizing organisms released
• free oxygen into the atmosphere,
• ultraviolet radiation converted some of it
• to elemental oxygen (O) and ozone (O3),
• both of which oxidize minerals more effectively
  than O2

55
Red Beds

• Once an ozone layer became established,
• most ultraviolet radiation failed
• to penetrate to the surface,
• and O2 became the primary agent
• for oxidizing minerals

56
Important Events in Life History

• Archean fossils are not very common,
• and all of those known are varieties
• of bacteria and cyanobacteria (blue-green algae),
  
• although they undoubtedly existed in profusion
• Likewise, the Early Proterozoic fossil record
• has mostly bacteria and cyanobacteria
• Apparently little diversification
• had taken place
• all organisms were single-celled prokaryotes,
• until about 2.1 billion years ago
• when more complex eukaryotic cells evolved

57
Gunflint Microfossils

• Even in well-known Early Proterozoic fossils
  assemblages, only fossils of bacteria are
  recognized

Photomicrograph of spheroidal and filamentous
microfossils from the Gunflint Chert of Ontario
Canada
58
Prokaryote and Eukaryotes

• An organism made up of prokaryotic cells is
  called a prokaryote
• whereas those composed of eukaryotic cells are
  eukaryotes
• In fact, the distinction between prokaryotes and
  eukaryotes
• is the basis for the most profound distinction
  between all living things

59
Lack of Organic Diversity

• Actually, the lack of organic diversity
• during this early time in life history
• is not too surprising
• because prokaryotic cells reproduce asexually
• Most variation in
• sexually reproducing populations comes from
• the shuffling of genes,
• and their alleles,
• from generation to generation
• Mutations introduce new variation into a
  population,
• but their effects are limited in prokaryotes

60
Genetic Variation in Bacteria

• A beneficial mutation would spread rapidly
• in sexually reproducing organism,
• but have a limited impact in bacteria
• because they do not share their genes with other
  bacteria
• Bacteria usually reproduce by binary fission
• and give rise to two cells
• having the same genetic makeup
• Under some conditions,
• they engage in conjugation during
• which some genetic material is transferred

61
Sexual Reproduction Increased the Pace of
Evolution

• Prior to the appearance of cells capable of
  sexual reproduction,
• evolution was a comparatively slow process,
• thus accounting for the low organic diversity
• This situation did not persist
• Sexually reproducing cells probably
• evolved by Early Proterozoic time,
• and the tempo of evolution increased

62
Eukaryotic Cells Evolve

• The appearance of eukaryotic cells
• marks a milestone in evolution
• comparable to the development
• of complex metabolic mechanisms
• such as photosynthesis during the Archean
• Where did these cells come from?
• How do they differ from their predecessors,
• the prokaryotic cells?
• All prokaryotes are single-celled,
• but most eukaryotes are multicelled,
• the notable exception being the protistans

63
Eukaryotes

• Most eukaryotes reproduce sexually,
• in marked contrast to prokaryotes,
• and nearly all are aerobic,
• that is, they depend on free oxygen
• to carry out their metabolic processes
• Accordingly, they could not have evolved
• before at least some free oxygen was present in
  the atmosphere

64
Prokaryotic Cell

• Prokaryotic cells
• do not have a cell nucleus
• do not have organelles
• are smaller and not nearly as complex as
  eukaryotic cells

65
Eukaryotic Cell

• Eukaryotic cells have
• a cell nucleus containing
• the genetic material
• and organelles

• such as mitochondria
• and plastids,
• as well as chloroplasts in plant cells

66
Eukaryotic Fossil Cells

• The Negaunee Iron Formation in Michigan
• which is 2.1 billion years old
• has yielded fossils now generally accepted
• as the oldest known eukaryotic cells
• Even though the Bitter Springs Formation
• of Australia is much younger --1 billion yrs old
• it has some remarkable fossils of single-celled
  eukaryotes
• that show evidence of meiosis and mitosis,
• processes carried out only by eukaryotic cells

67
Evidence for Eukaryotes

• Prokaryotic cells are mostly rather simple
• spherical or platelike structures
• Eukaryotic cells
• are larger
• much more complex
• have a well-defined, membrane-bounded cell
  nucleus, which is lacking in prokaryotes
• have several internal structures
• called organelles such as plastids and
  mitochondria
• their organizational complexity
• is much greater than it is for prokaryotes

68
Acritarchs

• Other organisms that were
• almost certainly eukaryotes are the acritarchs
• that first appeared about 1.4 billion years ago
• they were very common by Late Proterozoic time
• and were probably cysts of planktonic (floating)
  algae

69
Acritarchs

• These common Late Proterozoic microfossils
• are probably from eukaryotic organisms
• Acritarchs are very likely the cysts of algae

70
Late Proterozoic Microfossil

• Numerous microfossils of organisms
• with vase-shaped skeletons
• have been found
• in Late Proterozoic rocks
• in the Grand Canyon
• These too have tentatively been identified as
• cysts of some kind of algae

71
Endosymbiosis and the Origin of Eukaryotic Cells

• Eukaryotic cells probably formed
• from several prokaryotic cells
• that entered into a symbiotic relationship
• Symbiosis,
• involving a prolonged association of two or more
  dissimilar organisms,
• is quite common today
• In many cases both symbionts benefit from the
  association
• as occurs in lichens,
• once thought to be plants
• but actually symbiotic fungi and algae

72
Endosymbiosis

• In a symbiotic relationship,
• each symbiont must be capable
• of metabolism and reproduction,
• but in some cases one symbiont
• cannot live independently
• This may have been the case
• with Proterozoic symbiotic prokaryotes
• that became increasingly interdependent
• until the unit could exist only as a whole
• In this relationship
• one symbiont lived within the other,
• which is a special type of symbiosis
• called endosymbiosis

73
Evidence for Endosymbiosis

• Supporting evidence for endosymbiosis
• comes from studies of living eukaryotic cells
• containing internal structures called organelles,
  
• such as mitochondria and plastics,
• which contain their own genetic material
• In addition, prokaryotic cells
• synthesize proteins as a single system,
• whereas eukaryotic cells
• are a combination of protein-synthesizing systems

74
Organelles Capable of Protein Synthesis

• That is, some of the organelles
• within eukaryotic cells are capable of protein
  synthesis
• These organelles
• with their own genetic material
• and protein-synthesizing capabilities
• are thought to have been free-living bacteria
• that entered into a symbiotic relationship,
• eventually giving rise to eukaryotic cells

75
Multicelled Organisms

• Obviously multicelled organisms
• are made up of many cells,
• perhaps billions,
• as opposed to a single cell as in prokaryotes
• In addition, multicelled organisms
• have cells specialized to perform specific
  functions
• such as respiration,
• food gathering,
• and reproduction

76
Dawn of Multicelled Organisms

• We know from the fossil record
• that multicelled organisms were present during
  the Proterozoic,
• but we do not know exactly when they appeared
• What seem to be some kind of multicelled algae
  appear
• in the 2.1-billion-year-old fossils
• from the Negaunee Iron Formation in Michigan
• as carbonaceous filaments
• from 1.8 billion-year-old rocks in China
• as somewhat younger carbonaceous impressions
• of filaments and spherical forms

77
Multicelled Algae?

• Carbonaceous impressions
• in Proterozoic rocks, Montana
• These may be impressions of multicelled algae
• Skip next slide

78
The Multicelled Advantage?

• Is there any particular advantage to being
  multicelled?
• For something on the order of 1.5 billion years
• all organisms were single-celled
• and life seems to have thrived
• In fact, single-celled organisms
• are quite good at what they do
• but what they do is very limited

79
The Multicelled Advantage?

• For example, single celled organisms
• can not grow very large, because as size
  increases proportionately less of a cell is
  exposed to the external environment in relation
  to its volume
• and the proportion of surface area decreases
• Transferring materials from the exterior
• to the interior becomes less efficient

80
The Multicelled Advantage?

• Also, multicelled organisms live longer,
• since cells can be replaced and more offspring
  can be produced
• Cells have increased functional efficiency
• when they are specialized into organs with
  specific capabilities

81
Late Proterozoic Animals

• Biologists set forth criteria such as
• method of reproduction
• and type of metabolism
• to allow us to easily distinguish
• between animals and plants
• Or so it would seem,
• but some present-day organisms
• blur this distinction and the same is true
• for some Proterozoic fossils
• Nevertheless, the first
• relatively controversy-free fossils of animals
• come from the Ediacaran fauna of Australia
• and similar faunas of similar age elsewhere

82
The Ediacaran Fauna

• In 1947, an Australian geologist, R.C. Sprigg,
• in the Pound Quartzite in the Ediacara Hills of
  South Australia
• Additional discoveries by others turned up what
  appeared to be
• discovered impressions of soft-bodied animals
• impressions of algae and several animals
• many bearing no resemblance to any existing now
• Before these discoveries, geologists
• were perplexed by the apparent absence
• of fossil-bearing rocks predating the Phanerozoic

83
Ediacaran Fauna

• The Ediacaran fauna of Australia
• Tribrachidium heraldicum, a possible primitive
  echinoderm

Spriggina floundersi, a possible ancestor of
trilobites
84
Ediacaran Fauna

• Pavancorina minchami

• Restoration of the Ediacaran Environment

85
Ediacaran Fauna

• Geologists had assumed that
• the fossils so common in Cambrian rocks
• must have had a long previous history
• but had little evidence to support this
  conclusion
• The discovery of Ediacaran fossils and subsequent
  discoveries
• have not answered all questions about
  pre-Phanerozoic animals,
• but they have certainly increased our knowledge
• about this chapter in the history of life

86
Represented Phyla

• Three present-day phyla may be represented
• in the Ediacaran fauna
• jellyfish and sea pens (phylum Cnidaria),
• segmented worms (phylum Annelida),
• and primitive members of the phylum Arthropoda
  (the phylum with insects, spiders crabs, and
  others)
• One Ediacaran fossil, Spriggina,
• has been cited as a possible ancestor of
  trilobites
• Another might be a primitive member
• of the phylum Echinodermata

87
Distinct Evolutionary Group

• However, some scientists think
• these Ediacaran animals represent
• an early evolutionary group quite distinct from
• the ancestry of todays invertebrate animals
• Ediacara-type faunas are known
• from all continents except Antarctica,
• --were widespread between 545 and 670 million
  years ago
• but their fossils are rare
• Their scarcity should not be surprising, though,
• because all lacked durable skeletons

88
Other Proterozoic Animal Fossils

• Although scarce, a few animal fossils
• older than those of the Ediacaran fauna are known
  
• A jellyfish-like impression is present
• in rocks 2000 m below the Ediacara Hills Pound
  Quartzite,
• Burrows, in many areas,
• presumably made by worms,
• occur in rocks at least 700 million years old
• Wormlike and algae fossils come
• from 700 to 900 million-year-old rocks in China
• but the identity and age of these "fossils" has
  been questioned

89
Wormlike Fossils from China

• Wormlike fossils from Late Proterozoic rocks in
  China

90
Soft Bodies

• All known Proterozoic animals were soft-bodied,
• but there is some evidence that the earliest
  stages in the origin of skeletons was underway
• Even some Ediacaran animals
• may have had a chitinous carapace
• and others appear to have had areas of calcium
  carbonate
• The odd creature known as Kimberella
• from the latest Proterozoic of Russia
• had a tough outer covering similar to
• that of some present-day marine invertebrates

91
Latest Proterozoic Kimberella

• Kimberella, an animal from latest Proterozoic
  rocks in Russia

• Exactly what Kimberella was remains uncertain
• Some think it was a sluglike creature
• whereas others think it was more like a mollusk

92
Durable Skeletons

• Latest Proterozoic fossils
• of minute scraps of shell-like material
• and small tooth like denticles and spicules,
• presumably from sponges
• indicate that several animals with skeletons
• or at least partial skeletons existed
• However, more durable skeletons of
• silica,
• calcium carbonate,
• and chitin (a complex organic substance)
• did not appear in abundance until the beginning
• of the Phanerozoic Eon 545 million years ago

93
Proterozoic Mineral Resources

• Most of the world's iron ore comes from
• Proterozoic banded iron formations
• Canada and the United States have large deposits
  of these rocks
• in the Lake Superior region
• and in eastern Canada
• Thus, both countries rank among
• the ten leading nations in iron ore production

94
Iron Mine

• The Empire Mine at Palmer, Michigan
• where iron ore from the Early Proterozoic
  Negaunee Iron Formation is mined

95
Nickel

• In the Sudbury mining district in Ontario,
  Canada,
• nickel and platinum are extracted from
  Proterozoic rocks
• Nickel is essential for the production of nickel
  alloys such as
• stainless steel
• and Monel metal (nickel plus copper),
• which are valued for their strength and
  resistance to corrosion and heat
• The United States must import
• more than 50 of all nickel used
• mostly from the Sudbury mining district

96
Sudbury Basin

• Besides its economic importance, the Sudbury
  Basin,
• an elliptical area measuring more than 59 by 27
  km,
• is interesting from the geological perspective
• One hypothesis for the concentration of ores
• is that they were mobilized from metal-rich rocks
  
• beneath the basin
• following a high-velocity meteorite impact

97
Platinum and Chromium

• Some platinum
• for jewelry, surgical instruments,
• and chemical and electrical equipment
• is exported to the United States from Canada,
• but the major exporter is South Africa
• The Bushveld Complex of South Africa
• is a layered igneous complex containing both
• platinum
• and chromite
• the only ore of chromium,
• United States imports much of the chromium
• from South Africa
• It is used mostly in stainless steel

98
Oil and Gas

• Economically recoverable oil and gas
• have been discovered in Proterozoic rocks in
  China and Siberia,
• arousing some interest in the Midcontinent rift
  as a potential source of hydrocarbons
• So far, land has been leased for exploration,
• and numerous geophysical studies have been done
• However, even though some rocks
• within the rift are know to contain petroleum,
• no producing oil or gas wells are operating

99
Proterozoic Pegmatites

• A number of Proterozoic pegmatites
• are important economically
• The Dunton pegmatite in Maine,
• whose age is generally considered
• to be Late Proterozoic,
• has yielded magnificent gem-quality specimens
• of tourmaline and other minerals
• Other pegmatites are mined for gemstones as well
  as for
• tin, industrial minerals, such as feldspars,
  micas, and quartz
• and minerals containing such elements
• as cesium, rubidium, lithium, and beryllium

100
Proterozoic Pegmatites

• Geologists have identified more than 20,000
  pegmatites
• in the country rocks adjacent
• to the Harney Peak Granite
• in the Black Hills of South Dakota
• These pegmatites formed 1.7 billion years ago
• when the granite was emplaced as a complex of
  dikes and sills
• A few have been mined for gemstones, tin,
  lithium, micas,
• and some of the world's largest known
• mineral crystals were discovered in these
  pegmatites

101
Summary

• The crust-forming processes
• that yielded Archean granite-gneiss complexes
• and greenstone belts
• continued into the Proterozoic
• but at a considerably reduced rate
• Archean and Proterozoic greenstone belts
• differed in detail
• Early Proterozoic collisions
• between Archean cratons formed larger cratons
• that served as nuclei
• around which Proterozoic crust accreted

102
Summary

• One such landmass was Laurentia
• consisting mostly of North America and Greenland
• Important events
• in the evolution of Laurentia were
• Early Proterozoic amalgamation of cratons
• followed by Middle Proterozoic igneous activity,
• the Grenville orogeny, and the Midcontinent rift
• Ophiolite sequences
• marking convergent plate boundaries
• are first well documented from the Early
  Proterozoic,
• indicating that a plate tectonic style similar
• to that operating now had been established

103
Summary

• Sandstone-carbonate-shale assemblages
• deposited on passive continental margins
• are known from the Archean
• but they are very common by Proterozoic time
• The supercontinent Rodinia
• assembled between 1.3 and 1.0 billion years ago,
• fragmented,
• and then reassembled to form Pannotia about 650
  million years ago
• Glaciers were widespread
• during both the Early and Late Proterozoic

104
Summary

• Photosynthesis continued
• to release free oxygen into the atmosphere
• which became increasingly oxygen rich through the
  Proterozoic
• Fully 92 of Earth's iron ore deposits
• in banded iron formations were deposited
• between 2.5 and 2.0 billion years ago
• Widespread continental red beds
• dating from 1.8 billion years ago indicate
• that Earth's atmosphere had enough free oxygen
• for oxidation of iron compounds

105
Summary

• Most of the known Proterozoic organisms
• are single-celled prokaryotes (bacteria)
• When eukaryotic cells first appeared is
  uncertain,
• but they may have been present by 2.1 billion
  years ago
• Endosymbiosis is a widely accepted theory for
  their origin
• The oldest known multicelled organisms
• are probably algae,
• some of which may date back to the Early
  Proterozoic

106
Summary

• Well-documented multicelled animals
• are found in several Late Proterozoic localities
  
• Animals were widespread at this time,
• but because all lacked durable skeletons
• their fossils are not common
• Most of the world's iron ore produced
• is from Proterozoic banded iron formations
• Other important resources
• include nickel and platinum