Earth 209 Final-3 PDF

Summary

This document contains information on stratigraphy and geological time. It discusses principles of stratigraphy, contributions to geology, and fossil ranges. It also includes information about radioactive decay and the geological time scale.

Full Transcript

STRATIGRAPHY AND GEOLOGICAL TIME
Steno’s Principles of Stratigraphy
Principle of Layer Superposition: In undisturbed strata, the oldest layer lies at the bottom and the youngest at the top.
Principle of Layer Successive Formation: When a layer was forming, there was only liquid (like water) above it, and none of
the layers we see now on top of it had been formed yet
Principle of Original Layer Horizontality: Sedimentary layers are initially horizontal; inclined layers suggest crustal
disturbance
Principle of Lateral Layer Continuity: Layers extend laterally until they thin out or encounter a barrier.
Layer Terminations - 1774: First scientific attempt to estimate Earth’s age (~70,000 years). This challenged creationist ideas
and paved the way for modern geochronology.
Interpreting Stratigraphical Successions:
- Sedimentological Data: Structures like mudcracks and ripple marks help determine original depositional environments.
- Normal Succession: Younger layers lie atop older ones.
- Relative Ages by Superposition - Relative Ages: Layers in different sections can be correlated to establish their relative
chronological
- Inverted Succession: Tectonic forces may disrupt this order, overturned.
Contributions to Geology
Nicolaus Steno: Principles of stratigraphy (above). Earth (4.54 billion years old)
John Strachey: Layer terminations. Sir Charles Lyell: Principles for dating igneous and
Sir William Smith: Fossil-based correlation and metamorphic rocks.
geological mapping. Tomaso d’Arduinio: Use of sedimentary structures.
Georges Louis Leclerc (de Buffon): Age of the
Sir William Smith – Geological Society of England
Created the first geological map of England, Wales, Dubbed “the map that changed the world.”
and southern Scotland.
Fossil Ranges
Time period during which a particular species of organism existed
Index Fossils: Useful for matching layers in different areas, used to identify and date the layers of rock in which they are
found
Sir Charles Lyell’s Principles
Principle of Inclusions: The rock containing inclusions is intrusions of molten rock that form underground, they
younger than the included fragments. heat and "bake" both the layer above and the layer
Principle of Cross-Cutting Relations: Features like dikes below when they push in between existing rocks.
are younger than the rocks they cut through.
Relative Ages of Lava Flows: Lava flows across the
surface heat "bakes" rock layers below. Sills are younger
Radioactive Decay
Radioactive Decay: Unstable isotopes Half-Life Resolution: Provides a precise method for
spontaneously transform into stable daughter dating rocks and fossils.
isotopes. Decay Series: Example: Uranium-238 decays to
Half-Life: Time it takes for half the parent isotope to dating rocks and fossils. Lead-206 through a series of
decay into the daughter isotope. alpha and beta decay
Half-Life Resolution: Provides a precise method for steps.
dating rocks and fossils.
Geological Time Summary
Relative Geological Time Scale: Stratigraphy Proterozoic: Fossils include microscopic and
orders layers and fossils chronologically. macroscopic forms, longest
Eons of Earth’s History: Proterozoic/Phanerozoic Boundary: Cambrian
Hadean: Formation of Earth; no rock explosion where significant event of rapid increase in
Record. diversity and complexity of life forms
Hadean/Archean Boundary: Age of the oldest rock Phanerozoic: Visible fossils and complex life forms;
record in stratigraphical record divided into Paleozoic, Mesozoic, and Cenozoic eras.,
Archean: Oldest rocks and earliest fossil, shortest. shortest
Archean/Proterozoic Boundary: Banded iron Paleozoic Era: Periods include - Cambrian: Emergence
formation (see "Earth Rusting") of diverse marine life, the development of hard parts in
organisms, the formation of complex ecosystems, and Jurassic: Dominance of large dinosaurs, first birds, and
significant geological changes (longest), Ordovician: Saw the separation of the Pangaea, and Cretaceous: Further
the development of the first vertebrates and early evolution and diversification of dinosaurs and flowering
colonization of land by plants, shortest, Silurian: Marked plants (shortest). Marked by significant extinction events
by the appearance of the first vascular plants and rise of (e.g., Permian/Triassic crisis and Cretaceous/Paleogene
the jawed fish, Devonian: "Age of Fish" saw the rise of impact).
the first amphibians and land dwelling plants, Mesozoic/Cenozoic Boundary: Meteorite impact that
Mississippian:Dominance of marine life (ie.corals and lead to the extinction of several major fossil groups in
sponges), Pennsylvanian (or Carboniferous): vast coal both continental and marine realms, including dinosaurs
forests, the rise of early reptiles, and the development Cenozoic Era: Longest era, periods include Paleogene:
of significant mountain ranges, and Permian:Assembly Recovery and diversification of mammals and birds,
of the supercontinent Pangaea, shortest era Neogene: Saw the evolution of early humans and the
Paleozoic/Mesozoic Boundary: Permian/Triassic crisis spread of grasslands (longest), and Quaternary: Marks
affected mostly the species in the seas and oceans, 90% the development of humans and the most recent ice
became extinct during the crisis, most severe crisis in the age; fossils closely resemble modern life (longest)
history of life
Mesozoic Era: Periods include - Triassic: Rise of the
first dinosaurs, first mammals, recovery of life (longest),
FOSSIL RECORDS
What are Fossils?
Fossils: Vestiges of ancient life forms - Origin: Latin term meaning "to be dug out from the Earth," coined during
the Renaissance, Historical meaning: Included both minerals and vestiges of life.
Fossil Classifications
By Age: Fossils: Older than 11,700 years. Subfossils: Younger than 11,700 years (not all considered fossils), By Nature: Body
Fossils: Preserve parts of the organism (hard/soft body parts). Trace Fossils: Preserve organism activities (ie. movement
traces). Chemical Fossils: Preserve only small organic components.

Examples of Fossils
Body Fossils: Stony coral (cnidarian), Cephalopod Mixed Fossils: Mesolimulus (horseshoe crab) with
shells, Trilobite, Belemnites. movement traces.
Trace Fossils: Cruziana (movement trace), Skolithos
(vertical galleries), Acanthotheuthis (movement trace of
belemnite)
Historical Context
Pre-scientific Understanding: Fossilization Process
Fossils were known in early Antiquity. Transformation of a dead organism into a fossil.
Example: Brachiopod fossil from King Senwosret I’s Selective process: Not all organisms fossilize due to
time (Middle Kingdom, Egypt). its highly destructive nature.
First Scientific Report: Conditions for Fossilization
Xenophanes of Colophon (~570-475 B.C.): Rapid Burial: Sudden events (e.g., landslides) or
Described marine fossils found inland, suggesting high sedimentation rates.
past mixing of sea and land. Anoxic Conditions: Reduces decay, enhances
Locations: Syracuse, Paros, Melita, etc. preservation
Types of Fossilization
Casual Fossilization: (sea-urchin) )its highly destructive nature.
Petrification: Both lithification and permineralization Carbonization: Loss of elements except carbon during
Lithification: Transformation of hard body parts into decay (ie. Pecopteris (fern)
stony material Lepidodendron (lycopsid).
Permineralization: When something turns into stone Impressions: Formed by organism weight in sediment
because the pores get filled with minerals, (ie. Psaronius (ie. Pecopteris leaf)
(fern tree), Dinosaur bone, Cladoxylon(woody plant)) High-Quality Fossilization:
Recrystallization: Conversion of one mineral to Amber: Fossilized resin (e.g., Plesiomyrex).
another (e.g., aragonite to Tar Pits: Hydrocarbon swamps (e.g., Cybister).
calcite), (ie. Globotruncanella, Congealment, Dehydration:
Uintacrinus (sea-lily), Micraster Preservation of soft tissues.
Fossil Lagerstätten
Sites with exceptional fossil preservation, including soft tissues.
Examples: Burgess Shale (Canada): Middle Cambrian, e.g., Ottoia. & Chengjiang Fauna (China): Lower Cambrian, e.g.,
Haikouichthys (early vertebrate)

LIFE EMERGENCE ON EARTH AND EARLY EVOLUTION
CHON Elements - Dominant elements in life forms today: Carbon (C) (most dominant), Hydrogen (H), Oxygen (O), Nitrogen
(N) (Sulfur and phosphorus are present in smaller amounts.)
Earth’s Early Atmosphere - Alexandr Ivanovic Oparin (1896–1980): Postulated that CHON molecules could have formed
before life, giving rise to the first cells.
o Plant cells are too complex to form without a o Earth's original atmosphere was reducing,
o CHON molecules could accumulate in such o "Primordial soup" was not alive.
long inorganic evolution process. with little free molecular oxygen.
an atmosphere.
Isua Supercrustal Group
Location: Greenland. Graphite levels suggest organic origin.
Contains some of Earth’s oldest sedimentary rocks Rare oxides and carbonates; lack of layering.
(3.8–3.7 billion years old).
Experimental Confirmation - Miller-Urey Experiment (1953)
o Demonstrated that simple elements can o Produced seven amino acids (e.g., glycine,
chemically react to form organic CHON alanine).
molecules.
Polymerization
Formation of larger molecules (polymers) from simple Note: Molecules do not fossilize.
CHON molecules (monomers).
Example: Monosaccharides = Carbohydrates, Amino
acids = Protein
Isolated Cells:
Early Archean of Western Australia (Pilbara Strelley Pool Chert cyanobacteria: Chain-like
Craton): Apex Chert (volcano-sedimentary formation). structures similar to modern purple bacteria.
Evidence of early bacteria and
cyanobacteria debris.
Apex Chert cyanobacteria: Folded filament structures
made of carbon, similar to modern iron bacteria.
Stromatolites
Fossilized microbial structures (layered, rock-like photosynthetic bacteria (~1 mm).
structures) created by cyanobacteria Oxygen-depleted zone: Anaerobic bacteria
Patchy distribution - in Mesoarchean (1–2 cm).
Components (from surface to center): Stromatolite mass: Includes most of the stromatolite
Growth surface: Photosynthetic (mostly rock)
cyanobacteria and aerobic bacteria (~1
mm).
Undermat: Non-oxygen-producing
Banded Iron Formation (BIF)
Alternating thin layers of: Cherts and jaspers with lower iron content.
Iron oxides (e.g., hematite [Fe2O3] and Colors: Reddish (iron oxides) and green/grey
magnetite [Fe3O4]). (cherts/jaspers.
Oldest Eukaryotes
Biomarkers (chemical fossils): 2.1–1.8 billion years Assigned to red algae (rhodophytes) and
old. green algae (chlorophytes)
Bitter Springs Formation (Australia): Some fossils show cellular division and
True isolated eukaryote cells (1 billion years preserved nuclei.
old).
Eukaryote Examples:
Bangiomorpha: Algal Quaternary).
Filamentous microstructures Melanocyrillium:
thallus (similar to escaping from Resembles modern
modern red bag-like testate amoebas
Primitive holdfast acritarchs. (earliest animals).
for seafloor algae). Organic with
attachment. Survival sometimes
Age: ~1.2 billion adaptations for agglutinated
years dry/cold climates. particles.
(Proterozoic– Age: ~0.9 billion
Quaternary). years (Upper
Torridonophycus: Proterozoic–
Age: ~0.8–0.9 billion years (Upper
Proterozoic–Quaternary

DINOSAURS
Vertebrate Evolution - Vertebrates evolved from chordates in the Lower Cambrian. Early forms: Agnathans (jawless fish)
and jawed fishes. Key Examples: Haikouichthys: Earliest vertebrate. Sacabambaspis: Agnathan with a cephalic shield.
Fishes - Aquatic organisms with jaws, evolved in the Middle Silurian. Colonized marine, brackish, and freshwater
environments. Skeletons: Bony (most species) or cartilaginous (e.g., sharks). Dunkleosteus: Largest fish predator, Upper
Devonian, Ohio and Europe, fish, Macropomides: Late Cretaceous, Hjoula, Lebanon, fish
Amphibians - Transitioned to land: 1. Double respiration: lungs and skin (must remain wet). 2. Aquatic reproduction:
numerous unprotected eggs.
Reptiles - Evolved from amphibians with adaptations for land: Shelled eggs (fewer but protected). Fully terrestrial
lifestyle. Early reptiles: Diapsids (e.g., Hylonomus).
Synapsid Reptiles
Dominated Late Paleozoic to Early Triassic. Therapsids: Mammal-like reptiles
Developed thermoregulation. (e.g., Keratocephalus size of a rhinoceros - Late
Examples: Dimetrodon (predator). Devonian, Germany and Europe, therapsid)
Edaphosaurus (herbivore).
Diapsid Takeover and Dinosaur Origins
Dinosaurs evolved from diapsid reptiles during the Petrolacosaurus - Late Early Carboniferous, Kansas
Upper Triassic. USA, diapsid reptiles
Earliest dinosaurs: Possibly originated in South Hylonomous - Late Carboniferous, Canada, diapsid
America. reptiles
Early dinosauromorphs: Small, bipedal/quadrupedal Herrerasaurus example of early dinosaurs - Upper
insectivores or carnivores. Triassic, Argentina, dinosaur

Dinosaur Classification - Based on pelvic structure: Saurischians (lizard-hipped): Pubis points down/forward.
Ornithischians (bird-hipped): Pubis points backward
Theropods - Bipedal predators with knife-like teeth, grasping hands, hollow bones. Examples: Allosaurs: Dominant
predators of the Jurassic/Cretaceous..Tyrannosaurs: Apex predators (e.g., Tyrannosaurus Rex)
Sauropodomorpha - Early large dinosaurs; evolved into quadrupedal giants: Plateosaurus (Prosauropod, Europe, Upper
Triassic). Ultrasaurus (Sauropod, North America, Upper Jurassic).
Ornithischians - Herbivores with specialized adaptations: Stegosaurus: Beak-like structure for cropping plants.
Ankylosaurus: Armored "fused lizards" with osteoderms. Ceratopsians: Horned dinosaurs
(e.g., Triceratops).

Evolution of Flight
Examples: Dimorphodon: Ate small insects (Upper
Pterosauria (winged reptiles): Jurassic, Europe, pterosauria), Rhamphorhynchus: Ate
Lived from Upper Triassic to Cretaceous. fish, like seagulls (Upper Jurassic, Europe, pterosauria),
Initially considered gliders; later evidence Ctenochasma: Ate sea plankton and filtered out water
shows active flight. with teeth (Jurassic/Cretaceous, Europe, pterosauria),
Pteranodon Ate prey as whole (Upper Cretaceous, North Mesozoic.
America, pterosauria). Hypotheses for flight origins:
Avian Evolution: ▪ Arboreal: Gliding from trees.
Birds evolved from theropods in the Late ▪ Cursorial: Flapping during ground running
PLATE TECTONICS
Lithospheric Plates (ocean that has fully formed and stabilized over time,
Major Plates: Seven major plates (e.g., North Atlantic Ocean).
American, Pacific); composed of oceanic Aborted Oceans: Rifting without seafloor
lithosphere (oceanic crust + upper mantle) and/or spreading.
continental lithosphere (continental crust + upper Convergent:
mantle). Plates collide, forming subduction
Pacific Plate: Entirely oceanic, covering the Pacific zones or mountain ranges.
Ocean area. Types:
Minor Plates: Fragmented from major plates; may Ocean-Ocean: Subduction creates
evolve with or independently from parent plates. trenches and island arcs (e.g., Japan).
Key Discoveries Ocean-Continent: Oceanic crust
Alfred Wegener: Proposed "continental drift" in subducts beneath continental crust;
1915, noting geological and paleontological forms mountains (e.g., Andes).
similarities across continents (e.g., South America & Continent-Continent: Collision forms
Africa). mountains (e.g., Himalayas).
Gondwana Supercontinent: Identified by Eduard Transform: Plates slide past each other;
Suess using fossil evidence (e.g., Glossopteris flora, earthquakes common (e.g., San Andreas Fault).
Mesosaurus, Lystrosaurus). Wilson Cycle
Wegener’s hypothesis lacked a clear mechanism, Describes ocean formation, expansion, and closure.
thus initially rejected. Stages: Continental rifting → Seafloor
Oceanic Floor Features spreading → Ocean expansion →
Abyssal Plains: Flat areas; depth 4-4.5 km. Convergence → Ocean closure.
Mid-Oceanic Ridges: Submarine mountain chains; Current continents originated from
volcanic and seismic activity common. Pangea's breakup during the Mesozoic.
Oceanic Trenches: Deepest parts; sites of frequent North American Plate
earthquakes. Bordered by Pacific, Eurasian, African, South
Seamounts: Underwater mountains; volcanic American, Caribbean, and smaller plates (e.g., Juan
origins; can form islands. de Fuca, Cocos).
Island Arcs: Chains of volcanic islands parallel to Geological Evolution: First formed during the
trenches. breakup of Rodinia (Proterozoic Era).
Tectonic Regimes o Components: Cratonal PNA (stable
Divergent: core), Deformed PNA (tectonically
Plates move apart; features include rift zones (Earth's altered), and Terranes (displaced
crust stretches and breaks, forming long cracks), volcanic fragments).
activity (process where magma, gas, or ash escapes from Key Observations - Seafloor Age:
the Earth's surface, forming volcanoes or other Younger near mid-oceanic ridges; older near
features), and seafloor spreading (process where new continents.
oceanic crust forms as magma rises at mid-ocean ridges Magnetic Stripes: Parallel to mid-oceanic ridges,
and spreads outwards, pushing older crust away, confirming seafloor spreading.
Mid-Atlantic Ridge). Earthquakes/Volcanism: Concentrated along plate
Stages: Continental rift → Early oceanic boundaries.
Basin (body of water that forms when crust separates
and creates a depression, Red Sea) → Mature ocean
LATIN NAMES – STRUCTURALLY ORGANIZED WITH DEFINITIONS AND PERIODS
Early Life and Fossils
Cryptozoon: Precambrian stromatolitic structure, one of the earliest forms of life evidence.
Bangiomorpha: First known eukaryote with a filamentous thallus resembling modern red algae; ~1.2 billion years old. ST:
Proterozoic-Quaternary
Torridonophycus: Late Proterozoic algal microstructures escaping from a bag-like structure; resilient to harsh climates. ST:
Upper Proterozoic- Quaternary
 Melanocyrillium: Early testate amoeba-like eukaryote; ~0.8–0.9 billion years old, ST: Upper Proterozoic-Quaternary
Early Vertebrates
Haikouichthys: Earliest vertebrate; an agnathan from the Lower Cambrian with a primitive notochord, China.
Sacabambaspis: Early Ordovician agnathan with a cephalic shield, marking early jawless vertebrates, South America.
Dunkleosteus: Late Devonian large, armored placoderm predator; one of the largest fish of its time, Ohio and Europe, fish
Macropomides: Late Cretaceous,, Lebanon, fish
Reptilian Evolution
Hylonomus: First true reptile (diapsid); from the Late Carboniferous (~80 cm in length), Canada.
Mesosaurus: Early aquatic reptile; a key fossil in supporting continental drift theory.
Edaphosaurus: Vegetarian pelycosaur with a thermoregulatory sail on its back.
Dimetrodon: Predator pelycosaur with a dorsal sail, possibly used for thermoregulation (Early Permian, Texas)
Keratocephalus: Early therapsid, mammal-like reptile; adapted for heat retention. (Late Devonian, Germany and Europe)
*Dinosaurs*
Early Dinosaurs
Herrerasaurus: One of the oldest known dinosaurs from the Late Triassic, found in South America.
Theropods
Allosaurus: Large Jurassic predator; apex predator for 81 million years globally.( NA, EU, Asia, theropoda)
Tyrannosaurus: Cretaceous apex predator; likely originated in Asia before appearing in North America, theropoda.
Sauropodomorphs
Plateosaurus: Prosauropod from the Upper Triassic, showing an early stage of sauropodomorph evolution (Europe)
Ultrasaurus: A large sauropod from the Upper Jurassic (USA and North America).
Ornithischians
Stegosaurus: Upper Jurassic herbivore with distinctive plates and spiked tail; chewed foliage using beak and cheek
muscles (North America and Europe).
Ankylosaurus: Upper Cretaceous "fused lizard" with a shield of osteoderms and a robust, armored body (NA, EU, Asia)
Triceratops: Large Cretaceous herbivore with three horns and a frill for display or defense (North America)
Flying Reptiles
Sordes: Upper Jurassic pterosaur with evidence of fur-like structures, suggesting thermoregulation (Kazakhstan).
Pteranodon: Late Cretaceous flying reptile with a large crest and no teeth, suggesting specialized feeding.
Evolution of Birds
Rhamphorhynchus: Upper Jurassic pterosaur with a long tail and evidence of maneuverable flight.
Archaeopteryx: Late Jurassic transitional species between non avian dinosaurs and birds; key understanding the origin of
avian (related to birds) flight.