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The Dynamic Earth
ESSC 1010 The Dynamic Earth
Prof. Kennet E. Flores
Visualizing
Geology
3rd Edition
Barbara W. Murck
Brian J. Skinner
Chapter 6
Volcanoes and Igneous Rocks
1.
2.
3.
4.
Volcanoes and Volcanic Hazards
How, Why, and Where Rock Melts
Cooling and Crystallization
Plutons and Plutonism
Copyright © 2012 by John Wiley & Sons, Inc.
Volcanoes and Volcanic Hazards
Volcanoes
Volcano
•A vent through which lava, solid rock debris, volcanic ash, and
gasses erupt from Earth’s crust to its surface
Volcanoes
Volcano
•Can be explosive or nonexplosive
Volcanoes
Volcano
•The most common
perception of a volcano is of a
conical mountain, spewing
lava and poisonous gases
from a crater at its summit.
• This describes just one of
many types of volcano, and
the features of volcanoes are
much more complicated
http://video.nationalgeographic.com/video/news/150
220-volcano-drones-vin?source=relatedvideo
Volcanoes
Volcanic materials
•Lava, fragments of rock, and glassy volcanic ash
Volcanoes
Lava
•Molten rock that reaches Earth’s surface
Volcanoes
Pyroclast
• Fragment of rock ejected during volcanic eruptions
Volcanoes
Tephra
• All the pyroclasts ejecta from a volcano
• It range from car-size rocks (blocks) to ultrafine volcanic ash
Volcanoes
Bishop Tuff, Long Valley Caldera (California)
Clast size
Pyroclast
Tephra
(mainly unconsolidated
Pyroclastic rock
(mainly consolidated)
<0.063 mm Fine ash
Fine ash
Fine tuff
<2 mm
Coarse ash
Coarse ash
Corse tuff
<64 mm
Lapillus
Layer of lapilli or lapilli tephra
Lapilli tuff or lapillistone
>64 mm
Block, bomb
Agglomerate
Pyroclastic breccia
Volcanoes
Santorini, Greece
Mt. Etna, Sicily
Clast size
Pyroclast
Tephra
(mainly unconsolidated
Pyroclastic rock
(mainly consolidated)
<0.063 mm Fine ash
Fine ash
Fine tuff
<2 mm
Coarse ash
Coarse ash
Corse tuff
<64 mm
Lapillus
Layer of lapilli or lapilli tephra
Lapilli tuff or lapillistone
>64 mm
Block, bomb
Agglomerate
Pyroclastic breccia
Volcanoes
Clast size
Pyroclast
Tephra
(mainly unconsolidated
Pyroclastic rock
(mainly consolidated)
<0.063 mm Fine ash
Fine ash
Fine tuff
<2 mm
Coarse ash
Coarse ash
Corse tuff
<64 mm
Lapillus
Layer of lapilli or lapilli tephra
Lapilli tuff or lapillistone
>64 mm
Block, bomb
Agglomerate
Pyroclastic breccia
Volcanoes
The different kinds of eruptions and the volcanoes they build have
much to do with the physical properties of the magma that lies
at their source
Volcanoes
Magma
•Molten rock, which may include gas and fragments of rock,
volcanic glass and ash
Eruptions, Landforms, and Materials
Volcanoes and eruptions
VEI
Plume height
Eruption type
Frequency
Example
0
<100 m (330 ft)
Hawaiiann
Continuous
Kilauea
1
100–1,000 m (300–
3,300 ft)
Hawaiian/Strombolian
Months
Stromboli
2
1–5 km (1–3 mi)
Strombolian/Vulcanian
Months
Galeras(1992)
3
3–15 km (2–9 mi)
Vulcanian
Yearly
Nevado de
Ruiz (1985)
4
10–25 km (6–16 mi)
Vulcanian/Peléan
Few years
Eyjafjallajökull
(2010)
5
>25 km (16 mi)
Plinian
5–10 years
Mount St.
Helens (1980)
6
>25 km (16 mi)
Plinian/Ultra Plinian
1,000 years
Krakatoa
(1883)
7
>25 km (16 mi)
Ultra Plinian
10,000 years
Tambora
(1815)
8
>25 km (16 mi)
Ultra Plinian
100,000 years
Lake Toba (74
ka)
VEI: Volcanic Explosivity Index
Eruptions, Landforms, and Materials
Volcanoes and eruptions
Eruption types
It depends of two factors (a) Viscosity of the magma and (b)
amount of gas dissolved in it
Eruptions, Landforms, and Materials
Volcanoes and eruptions
Viscosity
• Degree to which a substance resists flow.
• A less viscous liquid is runny, whereas a more viscous liquid is
thick.
Eruptions, Landforms, and Materials
Volcanoes and eruptions
Volcanic Gases
• Water vapor, carbon dioxide, sulfur dioxide, etc.
• They can cause a volcano to explode
Eruptions, Landforms, and Materials
Volcanoes and eruptions
Hawaiian eruptions
https://www.youtube.com/watch?v=6VfsKoH-ScA
•Consist of very runny lava that flows easily
•These flows gradually build shield volcanoes
Eruptions, Landforms, and Materials
Volcanoes and eruptions
•
Shield volcanoes are broad, flat volcanoes with gently sloping
sides, built of successive lava flows
Eruptions, Landforms, and Materials
Volcanoes and eruptions
•
Tallest mountains in Earth (10 Km from b.s.l. to a.s.l.)
Eruptions, Landforms, and Materials
Volcanoes and eruptions
•
In shield volcanoes sometimes the lava rises to the surface
through long fissures rather than central craters
Eruptions, Landforms, and Materials
Volcanoes and eruptions
•
These fissures produce flood basalts or basalt plateaus
Eruptions, Landforms, and Materials
Volcanoes and eruptions
The classic volcano profile of a shield volcano
Eruptions, Landforms, and Materials
Volcanoes and eruptions
https://www.youtube.com/watch?v=6I5rC-ibqi4
Strombolian eruptions
•More explosive than Hawaiian
•Create loose volcanic rock called spatter cones or cinder cones
Eruptions, Landforms, and Materials
Volcanoes and eruptions
https://www.youtube.com/watch?v=mIX43uy4Zvg
Vulcanian eruptions
• More explosive than Strombolian and, as a result, can
generate billowing clouds of ash up to 10 km.
Eruptions, Landforms, and Materials
Volcanoes and eruptions
Pyroclastic flows are
hot volcanic
fragments (tephra),
buoyed by heat and
volcanic gases, flow
very rapidly
Vulcanian eruptions
• Produce pyroclastic flows
https://www.youtube.com/watch?v=Cvjwt9nnwXY
Eruptions, Landforms, and Materials
Volcanoes and eruptions
https://www.youtube.com/watch?v=CCujnt68bVg
Plinian eruptions
• Named after Pliny the Elder, who died during eruption of Mount
Vesuvius
Eruptions, Landforms, and Materials
Volcanoes and eruptions
Plinian eruptions
• Most violent eruptions, generating ash columns that can
exceed 20 kilometers
Eruptions, Landforms, and Materials
Volcanoes and eruptions
Plinian eruptions
• Produce steep-sided volcanoes, called stratovolcanoes
Eruptions, Landforms, and Materials
Volcanoes and eruptions
• Stratovolcanoes are composed of solidified lava flows
interlayered with pyroclastic material.
• Steep sides curve upward
Eruptions, Landforms, and Materials
The classic volcano profile of a stratovolcano
Eruptions, Landforms, and Materials
Other volcanic features
• Craters
Eruptions, Landforms, and Materials
Other volcanic features
• Resurgent dome
Eruptions, Landforms, and Materials
Other volcanic features
• Thermal spring
Eruptions, Landforms, and Materials
Other volcanic features
• Geysers
Eruptions, Landforms, and Materials
Other volcanic features
• Fumaroles
Volcanic Hazards
Volcanic Hazards
Deadly eruptions
Volcanic Hazards
Primary effects
•Lava flows
•Pyroclastic flows
•Volcanic gases
Secondary effects
•Related to, but not
a direct result of,
volcanic activity
• Fires
• Flooding
• Mudslides
• Debris
avalanche
Kalapana, Hawaii
Volcanic Hazards
Primary effects
•Lava flows
•Pyroclastic flows
•Volcanic gases
Secondary effects
•Related to, but not
a direct result of,
volcanic activity
• Fires
• Flooding
• Mudslides
• Debris
avalanche
Pompeii, Mt. Vesuvious
Volcanic Hazards
Primary effects
•Lava flows
•Pyroclastic flows
•Volcanic gases
Secondary effects
•Related to, but not
a direct result of,
volcanic activity
• Fires
• Flooding
• Mudslides
• Debris
avalanche
Lahar from Mount St Helens
Volcanic Hazards
Primary effects
•Lava flows
•Pyroclastic flows
•Volcanic gases
Secondary effects
•Related to, but not
a direct result of,
volcanic activity
• Fires
• Flooding
• Mudslides
• Debris
avalanche
Ijen, East Java
Volcanic Hazards
Tertiary and beneficial
effects
•Change a landscape
•Affect climate on
regional and global
scale
•Renew mineral content
and replenish fertility
•Geothermal energy
•Provide mineral
deposits
Volcanic Hazards
Tertiary and beneficial
effects
•Change a landscape
•Affect climate on
regional and global
scale
•Renew mineral content
and replenish fertility
•Geothermal energy
•Provide mineral
deposits
Volcanic Hazards
Tertiary and beneficial
effects
•Change a landscape
•Affect climate on
regional and global
scale
•Renew mineral content
and replenish fertility
•Geothermal energy
•Provide mineral
deposits
Volcanic Hazards
Tertiary and beneficial
effects
•Change a landscape
•Affect climate on
regional and global
scale
•Renew mineral content
and replenish fertility
•Geothermal energy
•Provide mineral
deposits
Volcanic Hazards
Tertiary and beneficial
effects
•Change a landscape
•Affect climate on
regional and global
scale
•Renew mineral content
and replenish fertility
•Geothermal energy
•Provide mineral
deposits
Predicting Eruptions
Volcano monitoring from the ground
Predicting Eruptions
Predicting Eruptions
Establishing a volcano’s
history
•Active
•Dormant
Monitoring changes and
anomalies
•Earthquakes
•Shape or elevation
•Volcanic gases
•Ground temperature
•Composition of water
Monitoring volcanoes from orbit
How, Why, and Where Rocks Melt
How, Why, and Where Rocks Melt
Geothermal gradient
Heat and pressure inside Earth
• Continental crust: temperature rises 30°C/km, then about
6.7°C/km.
• Ocean crust: temperature rises twice as rapid.
How, Why, and Where Rocks Melt
Effect of temperature and pressure on melting
How, Why, and Where Rocks Melt
Heat and Pressure Inside Earth
Fractional melt
•A mixture of molten and solid rock
How, Why, and Where Rocks Melt
Heat and Pressure Inside Earth
Fractionation
•Separation of melted materials from the remaining solid material
during the course of melting
How, Why, and Where Rocks Melt
Magma and Lava
•Magmas (therefore
lavas) differs in
composition,
temperature, and
viscosity
*molten rock below
surface (magma) vs.
magma when it reaches
the surface(lava)
Two types of lava flows
How, Why, and Where Rocks Melt
Magma and Lava
Composition
•45% to 75% of magma by weight is silica.
•Water vapor and carbon dioxide are
usually present
Temperature
•Lavas vary in temperature between
750°C and 1200°C
•Magmas with high H2O contents melt at
lower temperatures
Viscosity
•Lavas vary in their ability to flow
• Influenced by silica content and
temperature
How, Why, and Where Rocks Melt
Magma and Lava
Three types of magma
Basaltic
•45% to 50% of magma by weight is silica
•Little dissolved gas
•Oceanic crust
How, Why, and Where Rocks Melt
Magma and Lava
Three types of magma
Andesitic
•60% of magma by weight is silica.
•2-4% dissolved gas (mainly water
vapor)
•Subduction zones
How, Why, and Where Rocks Melt
Magma and Lava
Three types of magma
Rhyolitic
•70-75% of magma by weight is
silica
•3-8% dissolved gas (mainly water
vapor)
•Continents
How, Why, and Where Rocks Melt
Tectonic setting and volcanism
Divergent and convergent plate boundaries, and hotspots
How, Why, and Where Rocks Melt
Tectonic setting and volcanism
Oceanic, divergent margins
• Lava is thin with a steep geothermal gradient.
Midocean ridge: submarine basaltic pillow lavas
How, Why, and Where Rocks Melt
Tectonic setting and volcanism
Continental divergent margins
• Lava is high in silica.
Continental rift: rhyolitic and lavas with unusual composition
How, Why, and Where Rocks Melt
Tectonic setting and volcanism
Subduction zones
•Typically have high water content and melt at lower temperatures.
Ocean-ocean subduction zone
Ocean-continent subduction zone
How, Why, and Where Rocks Melt
Tectonic setting and volcanism
Hot spots
• Lava tends to be hot and basaltic and build giant shield
volcanoes
Shield volcano
Cooling and Crystallization
Cooling and Crystallization
Crystallization
•The process whereby mineral grains form and grow in
a cooling magma (or lava)
•Classified as:
• Volcanic
• Plutonic
Cooling and Crystallization
Rate of Cooling
Rapid cooling: Volcanic
rocks and textures
•Volcanic rock
• An igneous rock
formed from lava
• Glassy
• Aphanitic
• Porphyritic
• Pumice
• Vesicular basalt
Glassy texture
Cooling and Crystallization
Rate of Cooling
Rapid cooling: Volcanic
rocks and textures
•Volcanic rock
• An igneous rock
formed from lava
• Glassy
• Aphanitic
• Porphyritic
• Pumice
• Vesicular basalt
Aphanitic texture
Cooling and Crystallization
Rate of Cooling
Rapid cooling: Volcanic
rocks and textures
•Volcanic rock
• An igneous rock
formed from lava
• Glassy
• Aphanitic
• Porphyritic
• Pumice
• Vesicular basalt
Porphyritic texture
Cooling and Crystallization
Rate of Cooling
Slow cooling: Plutonic
rocks and textures
•Plutonic rock
• An igneous rock
formed underground
from magma
• Phaneritic: A
coarse-grained
texture
• Can have
exceptionally large
grains
Plutonic rock textures
Cooling and Crystallization
Chemical Composition
Igneous rocks subdivided into four categories based on silica
content: felsic, intermediate, mafic, and ultramafic
Cooling and Crystallization
Fractional crystallization
a) Filter pressing
b) Crystal settling
c) Crystal flotation
•Separation of crystals from liquids during crystallization
•This the reason of the diversity in kinds of igneous rocks
Cooling and Crystallization
Fractional crystallization
Bowen’s reaction series
•Predictable melting and cooling of minerals
Plutons and Plutonism
Plutons and Plutonism
Plutons
•Any body of intrusive igneous rock, regardless of size or shape
Plutons and Plutonism
Plutonic features
Batholith
A large, irregularly shaped
pluton that cuts across the
layering of the rock into
which it intrudes
Stock
Is a smaller version of a
batholith, only 10km or so its
maximum dimensions
Laccolith
A mushroom-shaped pluton
between pre-existing layers
Plutons and Plutonism
Batholiths are so huge that
map views give us the best
perspective.
Plutons and Plutonism
Plutonic features
Dike
A tabular pluton that runs
perpendicular to preexisting layers
They form when magma
squeezes into a crosscutting fracture and
solidifies
Plutons and Plutonism
Plutonic features
Sill
A sheet-like pluton that
is parallel to preexisting layers
They form when
magma intrudes
between two layers and
is parallel to them.
Plutons and Plutonism
Plutonic features
Dike
Plutons and Plutonism
Plutonic features
Sill
Plutons and Plutonism
Plutonic features
Volcanic neck
Remnant of a volcanic
pipe that once fed the
magma to the volcanic
vent
Plutons and Plutonism
Plutonic features
Devil’s Tower, Wyoming
Plutons and Plutonism
Xenoliths
A foreign rock
(preexisting rocks)
Plutons and Plutonism
Xenoliths