Lecture 2 — Earth Materials and Igneous Rocks
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Transcript Lecture 2 — Earth Materials and Igneous Rocks
CEE 437
Rocks!
Thomas Doe
Outline
Igneous Rocks
Sedimentary Rocks
Metamorphic Rocks
Rock Identification Lab
Rock Cycle
Crystallization at depth or
extrusion at surface
Igneous Rocks
Sediments
Lithification
Magma
Burial, metamorphism,
recrystallization
Weathering,
Erosion
Melting
Metamorphic
Rocks
Burial,
metamorphism,
recrystallization
Sedimentary Rocks
Northwest Igneous and
Metamorphic Rocks
Cascade Volcanoes
(recent)
Cascade Batholiths
(Felsic, CretMiocene)
Columbia River
Basalts
(miocene)
Recent
Basaltic
Volcanism
(Newberry
Crater)
Snake River
Basalts
(pliocene)
Yellowstone Region
Acidic Volcanics
(Pleistocene to
recent)
Geologic Settings for Igneous
Rocks
Oceanic
Hi Fe, Mg, Ca, low Si
basalt, gabbro
Continental
Hi Si, Na, K
granite, rhyolite, andesite
Igneous Origins
Intrusive
Batholithic or plutonic: phaneritic
Dikes or sills that chill rapidly: aphanitic
Extrusive
deposition as melt (lava)
pyroclastic
tuff
tephra
pyroclastic flows
Identifying Igneous Rocks
Chemistry
Acidic: Basic (more Si, less Si)
Texture
Aphanitic: crystals not visible
Phaneritic: made of visible crystal components
Porphyritic: Larger crustals in aphanitic or phaneritic
ground mass
Igneous Rock Classification
Acidic, Felsic
Basic, Mafic
Ultramafic
SERPENTINITE
Magma Generation on Continental
Margins
Magma Generation in Convergent
Continental Plate Margins
Extrusives
Viscosity varies with Si and water content
Basalt — low viscosity
Rhyolite — high viscosity
Rhyolite flows relatively unusual as rhyolite does
not flow well
Explosive
Tuffs, pyroclastics
Volcano Types
Basaltic: low
viscosity — Hawaii,
Columbia Plateau
Andesitic/Rhyolitic
Structures of Basalt Flows
Lava Tubes
Flow Stratigraphy
collonade
entablature
flow top breccia/scoria
Hawaii Basalt Flows
Basalt Flow Structures
Eruptions of Acid-Rock Volcanoes
Rhyolite Dome
Caldera
Mt. St. Helen’s Blast Zone
Mt. Mazama Ash Distribution
Sedimentary Rocks
Clastics, Siliciclastics, and Evaporites
Clastic rocks, depositional medium, and energy
Diagenesis — chemical changes after deposition
Rock Cycle
Crystallization at depth or
extrusion at surface
Igneous Rocks
Sediments
Lithification
Magma
Burial, metamorphism,
recrystallization
Weathering,
Erosion
Melting
Metamorphic
Rocks
Burial,
metamorphism,
recrystallization
Sedimentary Rocks
Sediment Sources
Clastic Sedimentary Rocks
Clastic — broken like iconoclast)
Often referred to as Siliciclastics as having Si
based rock forming minerals
Based on grain size and to a lesser extent
composition
Grain size related to energy of depositional
environment
Relationship of medium velocity to maximum grain
size)
Clastic Sedimentary Rocks
Clay, muds shales, mudstones, claystones
(difference based on fissility)
Silts siltstones
Sands sandstones
Gravels Conglomerates (Breccia if angular,
breccia may also be a term for tectonically
fragmented rock)
Weathering Cycle
Clastic Sediments
Clay Minerals
Sheets of linked silica tetrahedra sandwiching
octahedral layers of gibbsite composition, Al2(OH)6, or
brucite Mg3(OH)6
Major Clay Groups
kaolinite: single gibbsite layer
montmorillonite:weak water bonding between layers,
moderated by Ca, Na, or K (near-shore environments)
illite: K bonds between layers (off-shore environments)
bentonite: highly expansive, volcanic-derived, Na-rich
montmorillonite
Clay Structure
Clay Structure Cont’d.
Kaolinite
Illite
Montmorillonite
Lithification
Cementation
Crystallization
deposition of a material different from clasts
crystal growth on clasts to fill pore space
Compaction
Diagenesis
Early post-depositional chemical transformation of
sediments, e.g. calcite to dolomite
Carbonates
Generally like siliciclastics — carbonate muds,
sands, etc.
Often deposited in reefs
Major portion of world oil deposits
Properties depend strongly on post-depositional
pore chemistry
Cementation
Dissolution
Carbonate Environments
Evaporites
Rock salt (NaCl), Gypsum-Anhydrite (CaSO4),
Sylvite (KCl)
Deposition in regions where evaporation
exceeds recharge
desert lakes
restricted seas (Mediterranean)
lagoons, back-reef areas
Subject to flow and diapirism
Other Sedimentary Rocks
Chert: finely crystalline silica
as replacement/diagenetic nodules
as bedded material from silica-shelled biota
Coal
Derived from vegetation
Banded Iron Formation
Likely bacteria derived, mainly Pre-Cambrian
Sedimentary Rocks and Rock
Properties
Properties for a given geologic description vary
wildly based on cementation, porosity and other
diagenetic factors.
Properties can be strong anisotropic and
heterogeneous based on bedding
Depositional Environments
Synchroneity of deposition of different rock types
Sedimentary facies
Related to energy of environment
A rock unit is not everywhere the same age: Bright Angel
Shale
(example channels and banks in fluvial systems)
Energy related to topography, climate, and tectonic
activity
Sediment Sorting
Sedimentary Structure — Cross
Bedding
Fluvial and Lacustrine Environments
Fluvial
Channelization
Complex and close interrelationship of fine and
course sediments
Challenge for characterization due to high
variability
Special examples: glacial environments
Lacustrine
Deltaic deposits at margins, finer materials in lake
beds
Deltaic Environments
Variability based on proximity to source
Stratigraphy effected by progradation
Deltaic Development and
Sedimentary Facies
Continental Slope Environments
Turbidites and turbidity currents
Graded bedding
poor sorting
vertical zonation with fining upwards
Turbidites and Turbidity
Currents
Metamorphic Classification
Original Material
sandstone, limestone, shale, basalt)
Metamorphic Grade (Temperature, Pressure)
Source of Metamorphism (Regional, Contact)
Basic Metamorphic Types
Quartz Sandstone Quartzite
Limestone, Dolomite Marble
Shale
Slate — cleavage, no visible xl’s
Phyllite — foliation, mica sheen but xl’s not visible
Schist — clear foliation, visible mica
Gneiss — like granite but with foliation/gneissosity
Basalt greenschist, amphibolite
Non-foliated Metamorphic Rocks
Sandstone —> Quartzite
Limestone —> Marble
Dolomite —> Dolomitic Marble
Foliated Metamorphic Rocks
Shale/Mudstone
Slate
Phyllite (Greek for leaves e.g. phyllo dough)
Schist
Gneiss
Origin of Foliation (gneissosity,
schistosity)
Engineering Properties
Anisotropy of strength and elastic properties
Preferred failure on foliation
Slate
Phyllite
Schist
Chlorite Schist
Gneiss
Banded Gneiss
Metamorphic Grade
Subduction-Zone Metamorphism
Metamorphism at Continental
Collisions
Contact Metamorphism