Late Paleozoic Earth History

1
Chapter 11
Late Paleozoic Earth History
2
Tully Monster

• Tullimonstrum gregarium, also known as the Tully
  Monster is Illinoiss official state fossil
• Specimen from Pensylvanian rocks, Mazon Creek
  Locality, Illinois

• Reconstruction of the Tully Monster
• about 30 cm long

3
Mazon Creek Fossils

• Approximately 300 million years ago
• in the region of present-day Illinois,
• sluggish rivers flowed southwestward through
  swamps,
• and built large deltas that extended outward into
  a subtropical shallow sea
• These rivers deposited high quantities of mud
• that entombed many of the plants and animals
  living in the area
• Rapid burial
• and the formation of ironstone concretions
• preserved many of the plants and animals of the
  area

4
Pennsylvanian Delta Organisms

• During Pennsylvanian time, two major habitats
  existed in northeastern Illinois
• One was a swampy forested lowland of the
  subaerial delta,
• and the other was the shallow-marine environment
  of the actively prograding delta
• Living in the warm, shallow waters
• of the delta front were numerous
• cnidarians,
• mollusks,
• echinoderms,

• arthropods,
• worms,
• and fish

5
Swampy Lowlands

• The swampy lowlands surrounding the delta were
  home to more than 400 plant species,
• numerous insects,
• including millipedes and centipedes, as well as
  spiders
• and other animals such as
• scorpions and amphibians
• In the ponds, lakes, and rivers were many
• fish, shrimp, and ostracodes
• Almost all of the plants were
• seedless vascular plants,
• typical of the kinds that lived in the
  coal-forming swamps
• during the Pennsylvanian Period

6
Late Paleozoic Paleogeography

• The Late Paleozoic was a time of
• continental collisions,
• mountain building,
• fluctuating seas levels,
• and varied climates
• Coals, evaporites, and tillites
• testify to the variety of climatic conditions
• experienced by the different continents during
  the Late Paleozoic

7
The Devonian Period

• During the Silurian,
• Laurentia and Baltica collided along a convergent
  plate boundary
• to form the larger continent of Laurasia
• This collision,
• which closed the northern Iapetus Ocean,
• is marked by the Caledonian orogeny
• During the Devonian,
• as the southern Iapetus Ocean narrowed
• between Laurasia and Gondwana,
• mountain building continued along the eastern
  margin of Laurasia
• with the Acadian orogeny

8
Paleogeography of the World

• For the Late Devonian Period

9
Paleogeography of the World

• For the Early Carboniferous Period

10
Paleogeography of the World

• For the Late Carboniferous Period

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Paleogeography of the World

• For the Late Permian Period

12
The Kaskaskia Sequence

• Middle Devonian-Middle Mississippian
• The boundary with the Tippecanoe sequence is a a
  major unconformit.
• As the Kaskaskia Sea transgressed over the
  craton, the basal beds consisted of clean,
  well-sorted quartz sandstones

13
Oriskany Sandstone

• A good example is the Oriskany Sandstone
• of New York and Pennsylvania
• and its lateral equivalents

14
Basal Kaskaskia Sandstones

• Extent of the basal units of the Kaskaskia
  sequence in the eastern and north-central
  United States

15
Source Areas

• The source areas for the basal Kaskaskia
  sandstones
• were primarily the eroding highlands of the
  Appalachian mobile belt area,
• exhumed Cambrian and Ordovician sandstones
  cropping out along the flanks of the Ozark Dome,
• and exposures of the Canadian Shield in the
  Wisconsin area

16
Devonian Period

• Paleogeography of North America during the
  Devonian Period

17
Kaskaskian Rocks

• The majority of Kaskaskian rocks are
• carbonates, including reefs, and associated
  evaporite deposits

18
Major Reefs in Other Parts of the World

• In many other parts of the world, such as
• southern England,
• Belgium,
• Central Europe,
• Australia,
• and Russia,
• the Middle and early Late Devonian epochs were
  times of major reef building

19
Reef Development in Western Canada

• The Middle and Late Devonian-age reefs of western
  Canada
• contain large reserves of petroleum
• and have been widely studied from outcrops and in
  the subsurface
• These reefs began forming
• as the Kaskaskia Sea transgressed southward
• into Western Canada

20
Devonian Reef Complex

• Reconstruction of the extensive Devonian Reef
  complex of western Canada

• These reefs controlled the regional facies of the
  Devonian epeiric seas

21
Potash from Evaporites

• More than half of the world's potash,
• which is used in fertilizers,
• comes from these Devonian evaporites
• By the middle of the Late Devonian,
• reef growth stopped in the western Canada region,
  
• although non-reef carbonate deposition continued

22
Increased Detrital Deposition

• Deposition of black shales
• was brought on by the the Acadian orogeny

23
Widespread Black Shales

• These Upper Devonian-Lower Mississippian black
  shales are typically
• noncalcareous,
• thinly bedded,
• and usually less than 10 m thick

24
Extent of Black Shales

• The extent of the upper Devonian and Lower
  Mississippian Chattanooga Shale and its
  equivalent units
• such as the Antrion Shale and the Albany Shale

25
New Albany Shale

• Upper Devonian New Albany Shale,
• Button Mold Knob Quarry, Kentucky

26
The Late Kaskaskia

• Following deposition of the black shales,
• carbonate sedimentation on the craton dominated
  the remainder of the Mississippian Period

27
Mississippian Period

• Paleogeography of North America during the
  Mississippian Period

28
Mississippian Carbonates

• These Mississippian carbonates display
• cross-bedding, ripple marks, and well-sorted
  fossil fragments,
• all of which are indicative of a shallow-water
  environment
• Analogous features can be observed on the
  present-day Bahama Banks
• In addition, numerous small organic reefs
• occurred throughout the craton during the
  Mississippian
• These were all much smaller than the large
  barrier-reef complexes
• that dominated the earlier Paleozoic seas

29
Regression of the Kaskaskia Sea

• During the Late Mississippian regression
• of the Kaskaskia Sea from the craton,
• carbonate deposition was replaced
• by vast quantities of detrital sediments

30
Cratonwide Unconformity

• Prior to the end of the Mississippian,
• the Kaskaskia Sea had retreated
• to the craton margin,
• once again exposing the craton
• to widespread weathering and erosion
• This resulted in a cratonwide unconformity
• when the Absaroka Sea began Transgressing
• back over the craton

31
The Absaroka Sequence

• The Absaroka sequence
• includes rocks deposited
• during the latest Mississippian
• through Early Jurassic
• The extensive unconformity
• separating the Kaskaskia and Absaroka sequences
• essentially divides the strata
• into the North American
• Mississippian and Pennsylvanian systems

32
Pennsylvanian Period

• Paleogeography of North America during the
  Pennsylvanian Period

33
What Are Cyclothems?

• A cyclical pattern of alternating marine and
  nonmarine strata
• is one of the characteristic features of
  Pennsylvanian rocks
• Such rhythmically repetitive sedimentary
  sequences are known as cyclothems
• They result from repeated alternations
• of marine
• and nonmarine environments,
• usually in areas of low relief

34
Cyclothem

• Columnar section of a complete cyclothem

35
Pennsylvanian Coal Bed

• Pennsylvanian coal bed, West Virginia
• part of a cyclothem

36
Coal-Forming Swamp

• Reconstruction of the environment of a
  Pennsylvanian coal-forming swamp

37
The Okefenokee Swamp

• in Georgia, is a modern coal-forming environment,

similar to those occurring during the
Pennsylvanian Period
38
Ancestral Rockies

• During the Late Absaroka (Pennsylvania),
• the area of greatest deformation occurred in the
  southwestern part of the North American craton
• where a series of fault-bounded uplifted blocks
  formed the Ancestral Rockies
• Uplift of these mountains,
• some of which were elevated more than 2 km along
  near-vertical faults,
• resulted in the erosion of the overlying
  Paleozoic sediments
• and exposure of the Precambrian igneous and
  metamorphic basement rocks

39
Pennsylvanian Highlands

• Location of the principal Pennsylvanian highland
  areas and basins of the southwestern part of the
  craton

40
Ancestral Rockies

• Block diagram of the Ancestral Rockies, which
  were elevated by faulting during the
  Pennsylvanian Period

• Erosion of these mountains produced
• coarse red sediments
• that were deposited in the adjacent basins

41
Red bed Sediment

• As the Ancestral Rocky mountains eroded,
• tremendous quantities of
• coarse, red arkosic sand and conglomerate
• were deposited in the surrounding basins
• These sediments are preserved in many areas
• including the rocks of the Garden of the Gods
  near Colorado Springs
• and at the Red Rocks Amphitheater near Morrison,
  Colorado

42
Garden of the Gods

• Storm-sky view of Garden of the Gods from Near
  Hidden Inn, Colorado Springs, Colorado

43
Intracratonic Mountain Ranges

• It is thought that the collision of Gondwana with
  Laurasia produced great stresses in the
  southwestern region of the North American craton
• These crustal stresses were relieved by faulting
• that resulted in uplift of cratonic blocks
• and downwarp of adjacent basins,

44
The Late Absaroka

• While the various intracratonic basins
• were filling with sediment
• during the Late Pennsylvanian,
• the Absaroka Sea slowly began retreating from the
  craton
• During the Early Permian,
• the Absaroka Sea occupied a narrow region
• from Nebraska through west Texas

45
Permian Period

• Paleogeography of North America during the
  Permian Period

46
Middle Permian Absaroka Sea

• By the Middle Permian,
• the sea had retreated to west Texas
• and southern New Mexico
• The thick evaporite deposits
• in Kansas and Oklahoma
• provide evidence of the restricted nature of the
  Absaroka Sea
• during the Early and Middle Permian

47
Restricted Absaroka Sea

• Three basins separated by two submerged platforms
  formed during the Permian

48
Permian Reefs and Basins

• Location of the west Texas Permian basins and
  surrounding reefs

49
Massive Reefs

• Massive reefs grew around the basin margins
• while limestones, evaporites, and red beds were
  deposited
• in the lagoonal areas behind the reefs
• As the barrier reefs grew and the passageways
  between the basins became more restricted,
• Late Permian evaporites gradually filled the
  individual basins

50
Capitan Limestone Reef Reconstruction

• Reconstruction of the Middle Permian Capitan
  Limestone reef environment
• Shown are brachiopods, corals, bryozoans and
  large glass sponges

51
Capitan Limestone

• Spectacular deposits representing the geologic
  history of this region
• can be seen today in the Guadalupe Mountains of
  Texas and New Mexico
• where the Capitan Limestone forms the caprock of
  these mountains
• By the end of the Permian Period,
• the Absaroka Sea had retreated from the craton
• exposing continental red beds
• over most of the southwestern and eastern region

52
Antler orogeny at the Cordilleran Mobile belt

• A collision between
• this eastward-moving island arc
• and the western border of the Laurasia
• during the Late Devonian and early Mississippian,
  
• produced in a highland area
• This orogenic event,
• the Antler orogeny,
• caused by subduction and closure of a narrow
  ocean basin

53
Antler Highlands

• Reconstruction of the Cordilleran mobile belt
  during the Early Mississippian

• in which deep-water continental slope deposits

• were thrust eastward
• over shallow-water continental shelf carbonates
• forming the Antler Highlands

54
Ouachita Mobile Belt

• The Ouachita mobile belt
• extends for approximately 2100 km
• from the subsurface of Mississippi
• to the Marathon region of Texas
• Approximately 80 of the former mobile belt
• is buried beneath a Mesozoic and Cenozoic
  sedimentary cover
• The two major exposed areas in this region are
• the Ouachita Mountains of Oklahoma and Arkansas
• and the Marathon Mountains of Texas

55
Beginning of the Ouachita Orogeny

• During the Late Proterozoic to Early
  Mississippian,
• shallow-water detrital and carbonate sediments
• deposited on a broad continental shelf,
• while bedded cherts and shales accumulated in
  deeper-water
• Beginning in the Mississippian Period,
• the region changed from a passive continental
  margin to an active convergent plate boundary,
• marking the beginning of the Ouachita orogeny

56
Ouachita Mobile Belt

• Plate Tectonic model for the deformation of the
  Ouachita mobile belt
• Depositional environment prior to the beginning
  of orogenic activity

57
Ouachita Mobile Belt

• Incipient continental collision between
  North America and Gondwana began during
  the Mississippian to Pennsylvanian

58
Ouachita Mobile Belt

• Continental collision continued during the
  Pennsylvanian Period

59
Gondwana/Laurasia Collision

• The collision of Gondwana and Laurasia
• is marked by the formation of a large mountain
  range,
• most of which was eroded during the Mesozoic Era
• Only the rejuvenated Ouachita and Marathon
  Mountains exposed

60
Three Continuous Mobile Belts

• The Ouachita deformation
• was part of the general worldwide tectonic
  activity
• that occurred when Gondwana united with Laurasia
• Three mobile belts
• the Hercynian,
• Appalachian,
• and Ouachita
• were continuous, and marked the southern boundary
  of Laurasia

61
Caledonian Orogeny

• The culmination of the Caledonian orogeny
• occurred during the Late Silurian and Early
  Devonian
• with the formation of a mountain range
• along the western margin of Baltica

62
Acadian Orogeny

• The third Paleozoic orogeny to affect Laurentia
  and Baltica
• began during the Late Silurian
• and concluded at the end of the Devonian Period
• The Acadian orogeny affected the Appalachian
  mobile belt

63
Catskill Delta Red Beds

• The red beds of the Catskill Delta
• derive their color from the hematite found in the
  sediments
• Plant fossils and oxidation of the hematite
  indicate
• that the beds were deposited in a continental
  environment

64
The Old Red Sandstone

• The red beds of the Catskill Delta
• have a European counterpart
• in the Devonian Old Red Sandstone
• of the British Isles

65
Old Red Sandstone

• Old Red Sandstone on one side
• and the Catskill Delta on the other

66
Closing of the Iapetus Ocean

• The Taconic, Caledonian, and Acadian orogenies
• were all part of the same orogenic event
• related to the closing of the Iapetus Ocean

67
Hercynian-Alleghenian Orogeny

• Following this,
• the Hercynian-Alleghenian orogeny began,
• followed by orogenic activity
• in the Ouachita mobile belt
• The Hercynian mobile belt
• of southern Europe
• and the Appalachian and Ouachita mobile belts
• of North America
• mark the zone along which Europe
• as part of Laurasia
• collided with Gondwana

68
Pangaea

• These three Late Paleozoic orogenies
• Hercynian,
• Alleghenian,
• and Ouachita
• represent the final joining of Laurasia and
  Gondwana
• into the supercontinent Pangaea
• during the Permian