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Title: GLY 150: Earthquakes and Volcanoes Spring 2005: 020805


1
GLY 150 Earthquakes and VolcanoesSpring 2005
02/08/05
Lava flows at Kilauea Volcano, Hawaii
Lecture 8
Pyroclastic flows enter the ocean at Soufriere
Hills, Montserrat, West Indies
2
AnnouncementsGLY 150 Earthquakes and Volcanoes
  • The next journal assignment is due this Thurs.
    If you still have questions regarding the grading
    the grading criteria please see me or the T.A.
  • Your latest HW assignment is due this Thurs.
  • Your first exam will be on Tues. 02-15-2005.
  • We want you to understand the material so please
    come to see us if you are still unsure about any
    of the topics discussed in class
  • Test questions will can come from the text,
    quizzes, and lectures
  • Test questions will be multiple choice,
    true/false, and matching
  • I will answer questions in class on the Thurs.
    before the exam so please come with questions
  • Instructor office hours have changed to Mon.
    200-300 and Wed. 200-300

3
Figure Sources
  • Diagrams of each of the fault types are shown in
    your Natural Disasters test (Chapter 3)
  • Figures 3.8 through 3.13 are particularly
    helpful
  • Remember, use your texts to supplement the
    lecture notes. Many of the same figures can be
    found there
  • I have placed asterisks on the websites that most
    of the other figures came from. You should
    definitely look at these sites, read the material
    related to the figures, and be sure that you are
    well acquired with the figures.
  • The last question on this weeks homework session
    is designed help relate the different faulting
    terminology and provide a study guide for your
    first exam.

4
Events this QuarterSpring 2005
5
Where is Magma Erupted?
  • a. Mid-Ocean Ridges
  • Greatest volume of erupted magma, basaltic
  • b. Subduction Zones
  • Slab sinks and water migrates into overlying
    mantle
  • Lowers melting temperature of rocks so that they
    melt
  • Ocean-ocean subduction zones - island arcs
  • Oceanic-continental subduction zones - long,
    narrow mountain ranges
  • c. Within a Tectonic Plate
  • Hot mantle plumes (i.e. hot spots), perhaps
    rising from core-mantle boundary
  • e.g., Hawaii, Iceland

6
Where Volcanoes Occur
Intraplate Earthquake
  • Volcanism

No volcanism at continent-continent collision
zones or transform boundaries
Modified from Dynamic Earth http//pubs.usgs.gov/
publications/text/Vigil.html
7
Worldwide Distribution of Volcanoes
8
Magma GenerationProcess
  • As subducted slab heats up, fluids and other
    volatiles driven from subducting slab (100-200 km
    depth)
  • Water filled ocean sediments are primary source
    of fluid
  • Fluid rises into overlying mantle wedge where it
    causes partial melting
  • Volatiles decrease the melting temperature of
    materials in wedge
  • Volatiles increase magmas explosivity
  • Resulting magma rises buoyantly (brut force or
    through cracks) into the overlying crust, thereby
    supplying magma for arc volcanism

9
Subduction ZonesWhy is the Subduction Zone
Volcanism Explosive?
  • Magma produced at
  • subduction zones
  • Is high viscosity so that bubbles cannot
    expand/escape
  • Has a high silica content (derived from melting
    of crustal rocks)
  • Erupts at lower temperature
  • Contains a lot of volatiles
  • Ocean sediments atop subducted oceanic plate
    contain lots of water
  • Carbonate from marine animals produces carbon
    dioxide when heated
  • Mantle wedge
  • Release of volatiles from the crust when heated
    by ascending magma
  • REMEMBER Erupted magma is NOT derived from
    melting of the subducted oceanic plate instead
    derived from melted material in the mantle wedge
    (induced by raising volatiles)

10
Hot SpotsFormation of Hot Spot Tracks
  • Plumes are stationary for millions of years
  • Provide a continuous source of magma
  • As the tectonic plate moves over stationary
    mantle plumes, a line of volcanoes is formed
  • Only the volcanoes immediately above the plume
    are active
  • As volcanoes move away from the plume they become
    extinct and the ocean starts to erode them

11
Volcanic BehaviorViscosity
  • Viscosity Ability to flow
  • The lower the viscosity the more fluid the
    behavior
  • Water (low viscosity) flows faster then honey
    (high viscosity)
  • Low viscosity magma flow like ice-cream on a hot
    day
  • High viscosity magma hardly flows at all
  • Higher Temperatures lowers viscosity
  • Silica and oxygen content increase the
    viscosity
  • Increased content of minerals (i.e. crystallized
    minerals) increases the viscosity

12
Factors Affecting Magma ExplosivityVolatile
Content
  • Volatile Content how much gas is contained in
    the magma
  • Pepsi has a higher volatile content than water
  • Volatiles include water/steam, carbon dioxide,
    etc.
  • Gas content can range from 5
    (Mt. St. Helens) by weight
  • The higher the volatile content, the more
    explosive the magma

Mageik Volcano, Alaska
http//volcanoes.usgs.gov/About/What/Monitor/Gas/s
ample.html
13
Volcanic BehaviorVolatile Content
  • Volatile
  • Dissolved gas contained in the magma
  • Solubility in magma increases as pressure
    increases and temperature decreases
  • Analogues to a soda pop under pressure by the
    bottle cap.
  • When the cap is removed, reducing the pressure
    volatiles (CO2) gas escapes
  • As the uncapped bottle warms, more volatiles are
    released (i.e. the soda goes flat)
  • In low viscosity magmas gas easily escapes so
    pressure in the magma does not build up leading
    to non-explosive eruptions
  • In high viscosity magmas gas becomes trapped in
    the magma causing pressures to increase.
  • When the pressure is reduced, the dissolved
    gasses, the gasses expand in volume.
  • Because they cannot escape the high viscosity
    magma an explosion results

14
Formation of Explosive EruptionsBubble Formation
(a.k.a. vesiculation)
  • As the pressure decreases as magma rises to the
    surface, bubbles form when volatiles initially
    dissolved in the magma come out of solution to
    form gas bubbles. This process is called
    vesiculation.
  • As the magma rises further, the gas bubbles
    become more numerous and, and if the magma is
    fluid enough, existing bubbles also grow larger
    and escape as the magma as it rises

15
Formation of Explosive EruptionsBubble
Fragmentation
  • In viscous magmas, the pressure inside the
    bubbles becomes so great that they burst (a.k.a.
    fragment) allowing the gas inside the bubbles to
    suddenly and catastrophically expand
  • This sudden expansion of gas is what propels
    explosive eruptions (gas thrust region)
  • Once volatiles are expended in main explosive
    eruption, thick viscous lava flows may follow
  • Results in alternating ash and lava layers
    observed at stratovolcanoes

Buoyant Plume
Magma Chamber (dissolved gasses)
Similar to figure 6.8 in your text
16
Where are the Major Volcanoes?
  • 80 are located at convergent boundaries,
    primarily subduction zones (explosive)
  • 900 around the Pacific Ring of Fire (primarily
    in New Zealand, Japan, Alaska, Mexico, Central
    America, and South America)
  • 250 in the Mediterranean
  • Approximately 20 are located along mid-oceanic
    ridges/spreading centers (effusive)
  • A small percentage are located at hot spots far
    from plate boundaries (e.g., Hawaii) (effusive)

17
Associated landform
Volcanic Types
Icelandic
Hawaiian
Stromboliian
  • Different eruptive types lead to different
  • explosivities (measure of eruptive power)
  • landforms

Vulcanian
Plinian
Caldera
From Natural Disasters, Figure 6.16 in your text
18
Volcanic Explosivity Index (VEI)Historic
Eruptions
  • In the last 10,000 yrs
  • 4 VEI 7 eruptions
  • 39 VEI 6 eruptions
  • 84 VEI 5 eruptions
  • 278 VEI 4 eruptions
  • 868 VEI 3 eruptions
  • 3477 VEI 2 eruptions

http//volcanoes.usgs.gov/Products/Pglossary/,
see page 167 in your text
19
Volcanic BehaviorSummary
  • Using the 3 Vs (viscosity, volatiles, volume) we
    can predict volcanic landforms

From Natural Disasters, Table 6.7 Class Text
20
Quiz
21
Quiz 4 Explosivity
  • (1 point) As VEI increases, the
  • volume of material erupted decreases
  • time between similar sized eruptions decreases
  • explosivity of the eruption increases
  • worldwide yearly rate of occurrence of this size
    of eruption increases
  • height of the eruptive column typically
    decreases
  • (1 point) In an eruption, fragmentation refers to
    the
  • nucleation of gas bubbles
  • explosive shattering of gas bubbles as they
    approach the surface because of high pressure
    inside the bubble
  • process of vesiculation
  • process of driving volatiles from the subducting
    plate via heating
  • differentiation of magma into viscous and
    non-viscous magmas
  • (2 points) Write 2-3 complete sentences
    discussing concepts you are having difficulty
    with, topics you think are particularly
    interesting, specific questions you might have,
    or topics you want to hear more about, etc.

22
Icelandic EruptionsIceland
http//pubs.usgs.gov/publications/text/Krafla.html
Krafla Volcano, 1977-1984
  • Combination hot spot and divergent plate boundary
    (oceanic-oceanic)
  • As tectonic plates moved about surface of the
    earth, oceanic spreading center coincidently
    moved over a hot spot
  • Double dose of volcanism created the topographic
    high which is Iceland
  • The only place on the mid-ocean ridge system that
    rises above sea-level

http//pubs.usgs.gov/publications/text/understandi
ng.htmlanchor5567033
23
IcelandFissure Eruptions
  • Fissure eruptions occur when stretched crust
    finally breaks and contracts back to an
    unstretched condition
  • Similar to elastic rebound model for earthquakes
  • Any single rifting event on 10s km long (a small
    fraction of entire rift system)
  • Extensive ground cracking parallel to the rift
  • Affects an area a few kms across
  • At any one location, rift events are infrequent,
    occurring only every few hundred years
  • Low Viscosity
  • Low Volatiles
  • Large Volume

Krafla Volcano, 1975-1984 (previous eruption 1724
-1728)
http//pubs.usgs.gov/publications/text/Krafla.html
24
Icelandic Eruptions (1984 Krafla erution)
  • Low Viscosity
  • Low Volatiles
  • Large Volume

Curtins of Fire
25
Icelandic Eruptions
  • Low Viscosity
  • Low Volatiles
  • Large Volume

26
Hawaiian Eruptions
  • Low Viscosity
  • Low Volatiles
  • Large Volume

Curtins of Fire
Spatter Cone
27
Kilauea Volcano, Hawaii A Typical Rift Eruption
  • Eventually, the rift eruption coalesces to a
    central vent
  • A stage of lava fountaining ensues
  • Low Viscosity
  • Low Volatiles
  • Large Volume

Puu O o Eruption 1983 to Present
http//volcanoes.usgs.gov/Imgs/Jpg/Tephra/
28
Kilauea Volcano, Hawaii A Typical Rift Eruption
  • Low Viscosity
  • Low Volatiles
  • Large Volume
  • Get alternating periods of lava fountaining and
    more gentle outpourings of lava
  • Behavior depends on volatile (gas) content of
    magma
  • Higher gas content leads to more explosive
    eruptions
  • A cinder cone is formed at the central vent

Puu O o Eruption 1983 to Present
http//volcanoes.usgs.gov/Products/Pglossary/
29
Kilauea Volcano, Hawaii A Typical Rift Eruption
  • As volatiles are expended, lava fountaining
    ceases and a lava lake is formed that fills the
    existing volcanic cone/crater
  • Produces Shield Volcanoes
  • Low Viscosity
  • Low Volatiles
  • Large Volume

Puu O o Eruption 1983 to Present
http//hvo.wr.usgs.gov/gallery/kilauea/erupt/1986t
o1991.html
30
Types of VolcanoesShield Volcanoes
  • Effusive eruptions of new volcanic material
  • Average lifetime 100,000 1,000,000 years
  • Both flank eruptions (eruptions from the side of
    the volcano) and summit eruptions are common
  • Typically form above hot spots
  • Low Viscosity
  • Low Volatiles
  • Large Volume

31
Types of VolcanoesShield Volcanoes
  • Broad, gentle slopes which are convex upward
    (like a warriors shield laid on the ground)
  • Layered - built by the repeated eruption of
    fluid, low viscosity lavas
  • Enormous volcanic edifices with huge footprint
    because
  • Lava flows across the ground easily
  • Lava can form tubes that enable lava to flow tens
    of kilometers from an erupting vent with very
    little cooling
  • Largest volcanoes on Earth

http//volcanoes.usgs.gov/Products/Pglossary/
Mauna Loa, Hawaii
32
Shield VolcanoesMauna Loa, Hawaii
  • Fissure eruption on the flank of the volcano
    (a.k.a. curtain of fire)
  • From a long vertical dike that has reached the
    surface

33
Types of VolcanoesFlood Basalts
  • Thick flat lying effusive basalt flows that form
    immense plateaus
  • Cover areas thousands of times larger than the
    largest volcano
  • Formed when a hot spot (i.e., mantle plume)
    penetrates continental crust
  • Associated with large emissions of potentially
    hazardous volcanic gas
  • Eroded flood basalts generate characteristic
    topography (a.k.a. traps)
  • Low Viscosity
  • Low Volatiles
  • Very Large Volume

34
Types of VolcanoesFlood Basalts
  • Major flood basalt provinces
  • India (Deccan Traps)
  • 1-2 km thick (3000-6000 ft)
  • Cover half-million square kilometers
  • Siberia (Siberian Traps)
  • Cover even larger area than the Deccan Traps
  • United States (Columbia River Flood Basalts)
  • Relatively small flood basalt province
  • Iceland
  • Ocean

http//vulcan.wr.usgs.gov/Volcanoes/ColumbiaPlatea
u/
35
Types of VolcanoesContinental Flood Basalts
  • Major flood basalt provinces
  • Siberia (Siberian Traps)
  • Cover even larger area than the Deccan Traps
  • United States (Columbia River Flood Basalts)
  • Relatively small flood basalt province
  • India (Deccan Traps)
  • 1-2 km thick (3000-6000 ft)
  • Cover half-million square kilometers
  • Iceland

36
Types of VolcanoesFlood Basalt Plateaus
Great Basin
  • Flood Basalts typically produce large volcanic
    plateaus with small shield volcanoes
  • Low Viscosity
  • Low Volatiles
  • Very Large Volume

Yellowstone
37
Types of VolcanoesStombolian Eruptions
  • May be relatively long-lived (yrs) with frequent
    eruptions
  • Built-up with pyroclastic material that eroded
    quickly leaving the resistant central conduit to
    form a spectacular volcanic necks
  • Produce cinder cones
  • Low/Medium Viscosity
  • Medium/High Volatiles
  • Small Volume

38
Pyroclastics(a.k.a. Tephra)
Ash and Pumice
  • Pyroclastic material fragments of volcanic rock
    and lava (regardless of size) blasted into air by
    explosions or carried upward by hot gases in
    eruption columns or lava fountains
  • Larger fragments usually fall near volcano
  • Smaller fragments may be transported far from the
    source

Blocks
Bombs
All from http//volcanoes.usgs.gov/Products/Pgloss
ary/
39
Types of VolcanoesCinder Cones
  • Moderately explosive eruptions of new volcanic
    material
  • Average lifetime 1-100 years
  • Frequently form on flanks and summits of larger
    shield and stratovolcanoes
  • Can also form independent of larger volcanic
    edifices
  • Generally produce stombolian-type eruptions
  • Low/Medium Viscosity
  • Medium/High Volatiles
  • Small Volume

40
Types of VolcanoesCinder Cones
  • Steep conical hills of volcanic fragments that
    accumulate around and downwind of the vent
  • Sides straight with slopes of 30 (angle of
    repose)
  • Pyroclastic material (a.k.a. tephra) ejected
    material of all sizes (a.k.a. ash, bombs,
    blocks, etc.)
  • Solid by the time it hits ground
  • Most numerous type of volcano
  • Small 10s to 100s of meters tall
  • Rarely reactivated (i.e., rarely erupt a 2cnd
    time)

Red Cones, Long Valley Caldera, California
Downwind Side
http//volcanoes.usgs.gov/Products/Pglossary/
41
Types of VolcanoesCinder Cones
Kilauea Iki, Hawaii
Stromboli, Italy
Downwind Side
http//volcanoes.usgs.gov/Products/Pglossary/strom
bolian.html
  • Low/Medium Viscosity
  • Medium/High Volatiles
  • Small Volume

Sunset crater, AZ
42
Types of VolcanoesVulcanian Eruptions
  • Begins with steam explosions that remove old lava
    from the central vent
  • Main eruptions characterized by eruption of
    viscous gas-rich magma. A cauliflower or
    mushroom shaped ash cloud develops. Lightning is
    common.
  • Pyroclastic material more widespread than in
    Hawaiian or Strombolian eruptions.
  • End of eruption characterized by viscous lava
    flows.
  • Can produce cinder cones or stratovocanoes
  • Medium/High Viscosity
  • Medium/High Volatiles
  • Small/Large Volume

43
Volcanic EruptionsPlinian Eruptions
  • Large, explosive eruptions
  • Form enormous dark columns of tephra and gas that
    extend high into the stratosphere (11 km)
  • Driven upward by buoyancy of hot gasses
  • Associated hazards
  • Pyroclastic flows and surges as eruptive column
    collapses
  • Extensive ash falls
  • Ash Clouds
  • High viscosity
  • High volatiles
  • Large volume

Mt. St. Helens, Washington
http//volcanoes.usgs.gov/Hazards/What/PF/PFMSH.ht
ml
44
Types of Volcanoes Plinian Eruptions
Mt. Pinatubo, Philippines, 1991
  • High viscosity
  • High volatiles
  • Large volume
  • Produced at Stratovalcanoes
  • Carries pyroclastic debris up to 50 km (30 miles)
    into the atmosphere.
  • Can affect climate
  • Generally the final phase in a major eruptive
    sequence
  • About 1-2 occur each century
  • e.g.Vesuvius and Pompeii

Abbot, Fig 6.25 in your text
45
Mount Vesuvius, ItalyPliny the Younger A.D. 79
- I
  • The cloud could best be described as more like
    an umbrella pine than any other tree, because it
    rose high up in a kind of trunk and then divided
    into braches. I imagined that this was because
    it was thrust up by the initial blast until its
    power weakened as it was left unsupported and
    spread out under its own weight. Sometimes it
    looked light-colored, sometimes it looked mottled
    and dirty with the earth and ash it had carried
    up. Like a true scholar, my uncle saw at once
    that it deserved closer study and ordered a boat
    to be prepared. He said that I could go with
    him, but I chose to continue my studies.

46
Types of VolcanoesStratovolcanoes (a.k.a.
composite volcanoes)
  • Explosive eruptions of new volcanic material
    extremely hazardous
  • Average lifetime 100,000 1,000,000 years
  • Both flank eruptions (eruptions from the side of
    the volcano) and summit eruptions are common
  • Form at subduction zones
  • High viscosity
  • High volatiles
  • Large volume

Mount Fuji, Japan
47
Types of VolcanoesStratovolcanoes (a.k.a.
composite volcanoes)
  • Steep, conical volcanoes
  • Slopes have a concave upward profile
  • Produce both highly explosive and effusive
    eruptions
  • Composed of alternating layers of pyroclastic
    material and viscous lava (i.e., they are
    stratified)
  • May have secondary vents with cinder cones and
    lava domes on flanks
  • Typically occur on the landward side of
    subduction zones

Mount Mageik, Alaska
http//volcanoes.usgs.gov/Products/Pglossary/
48
Types of VolcanoesStratovolcanoes (a.k.a.
composite volcanoes)
  • Stratovolcanoes often more complex then
    introductory schematics indicate
  • Ash layers extend further from vent than lava
    layers (lava is viscous)
  • Many secondary (a.k.a. parasitic) cones form on
    slopes of main edifice
  • High viscosity
  • High volatiles
  • Large volume

49
Types of VolcanoesStratovolcanoes
Mt. St. Helens, Washington
Masaya Volcano, Nicaragua
  • High viscosity
  • High volatiles
  • Large volume

http//volcanoes.usgs.gov/Hazards/What/PF/PFMSH.ht
ml
Mt. Rainier, Washington
50
Types of VolcanoesStratovolcanoes vs. Shield
Volcanoes
  • Shield volcanoes are significantly more
    voluminous than stratovolcanoes
  • Especially true when considering the size of the
    volcano at its base
  • Note the differing profiles (concave up vs.
    concave down) for the two types of volcanoes

http//vulcan.wr.usgs.gov/Imgs/Gif/VolcanoTypes/sh
ield_vs_composite.gif, See Fig 6.17 in your text
51
Types of VolcanoesLava Domes
  • Effusive eruption of new volcanic materials
  • Average lifetime 1-100 years
  • Usually form after the explosive eruption of
    gas-rich magma at stratovolcanoes (thus common at
    subduction zones)
  • High viscosity
  • Low volatiles
  • Small volume

52
Types of VolcanoesLava Domes
  • Rounded, steep-sided mounds of lava formed near
    the volcanic vent by very viscous magma
  • Magmas are typically too viscous (resistant to
    flow) to move far from the vent before cooling
    and crystallizing.
  • Consist of one or more individual lava flows
  • May plug the volcanic vent, allowing pressure to
    build up
  • Steep sided domes may collapse, generating
    pyroclastic flows

Mount St. Helens, Washington
http//vulcan.wr.usgs.gov/Volcanoes/MSH/Images/lav
a_dome.html
  • High viscosity
  • Low volatiles
  • Small volume

53
Lava Dome FormationMt. St. Helens, Washington
  • Grow by continuously adding new layers and lobes
    surrounded by slopes of talus (broken-up, loose
    pieces of rock)

http//vulcan.wr.usgs.gov/Imgs/Gif/MSH/Graphics/Do
mes/dome_growth_schematic_80-83.gif
http//vulcan.wr.usgs.gov/Imgs/Gif/MSH/Graphics/Do
mes/msh_lobes_80-81.gif
54
Types of VolcanoesLava Domes
http//vulcan.wr.usgs.gov/Glossary/Domes/images.ht
ml
Katmai Volcano, Alaska
High viscosity Low volatiles Small volume
Near Mono Lake, California
Mt. Lassen, California
55
Volcanic EruptionsPhreatic Eruptions
Mt. St. Helens, Washington, April 4, 1980
  • Produced when groundwater comes in contact with
    hot rock or magma and flashes to steam
  • No new magma is expelled
  • Only preexisting rock is erupted

http//volcanoes.usgs.gov/Products/Pglossary/Hydro
VolcEruption.html
56
Types of VolcanoesCalderas
  • Large, circular, steep-walled depression at the
    summit of a volcano
  • Up to 10s km in diameter
  • Walls up to 100s m high
  • Formed in hours to days
  • Average lifetime 100,000-1,000,000 years
  • Differ from craters which are smaller (circular depressions formed by the explosive
    evacuation of rock during eruptions

Aniakchak Caldera, Alaska
http//volcanoes.usgs.gov/Products/Pglossary/
  • High viscosity
  • High volatiles
  • Very large volume

57
Types of VolcanoesCalderas
High viscosity High volatiles Very large volume
  • Formed by
  • Explosive disintegration of the top of a volcano
    (typically a stratovolcano)
  • Collapse of the top of a volcano into an
    underground magma reservoir due to a loss of
    structural support after magma has withdrawn or
    been erupted
  • Volcano collapses or subsides into emptied space
  • Caldera collapse associated with great eruptions

58
Types of VolcanoesOverview
  • Volcanoes come in a variety of sizes and shapes
  • Their shapes are a result of the
  • types of magma erupted
  • processes and types of eruptions that formed them

mid-ocean ridge volcanism continental flood b
asalts
59
Types of VolcanoesOverview
  • Flood Basalts

http//vulcan.wr.usgs.gov/Photo/Pictograms/volcano
_types.html
60
Types of Volcanoes
http//vulcan.wr.usgs.gov/Glossary/VolcanoTypes/vo
lcano_types.html
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