Title: Volcanism and volcanic rocks
1Volcanism and volcanic rocks
- rocks and sediments produced by volcanic
processes
2Volcanism plate tectonics
- relationship of volcanism to movements of the
earths plates (fig 7.1)
3convergent boundaries
- seduction zones often violent eruptions, due to
high silica content - pyroclastic sediments thrown from the volcano
4divergent margins rifting
5divergent margins rifting
- under oceans
- basaltic lava pillow lava
- non violent eruptions,
- composition of gabbro,
- low silica content,
- created by partial melting of the low-temperature
constituents of the mantle
- on land
- plateau basalts
- non violent eruptions of
- basalt flows from fissures (Iceland)
- mantel material
6divergent margins rifting
- under oceans
- basaltic lava pillow lava
7hot spots
- stationary heat plumes in the mantle, hot spots
in the mantle produce volcanoes in a chain as the
crust moves over the hot spot (Hawaiian Islands)
8Eruptive Phenomena include
- lava flows
- explosions
- ash falls
- hot-ash flows
- glowing avalanches
- mudflows
- fissures
- earthquakes
- floods
- elevation changes
- gas discharges
9- mudflows
- fissures
- earthquakes
- floods
- elevation changes
- gas discharges
- lava flows
- explosions
- ash falls
- hot-ash flows
- glowing avalanches
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11types of lava
- basic lava produce non explosive eruptions or
effusive eruptions, with lava fountains and lava
flows, less viscous and thus does not trap gasses
as much as the lava below - intermediate and acidic lava produce explosive
eruptions sudden release of trapped CO2 and SO2
and steam in the highly viscous lava
12types of lava
13types of lava
- intermediate / acidic lava
14Warnings of an eruptionFig 7.5- 7.7 mt. st.
helens
- begins with upward movement of magma from 50 km
depth in the crust - earthquake swarms up to hundreds per day due to
the rise of magma - earthquakes at 1 km depth when the eruption is
nearer at hand - temperature rise in hot springs and steam in
volcanic crater - gas released causes asphyxiation
- snow on the volcano will melt
- bulge of the surface
- explosion casting pyroclastic debris up into
the atmosphere (known up to 80 km) - Fall of pyroclastic debris (hot material)
- base surge outward expanding ash-laden cloud
which sometimes also contains poisonous acid or
toxins
15On May 18, 1980, Mount St. Helens had a massive
explosion that forever changed the picturesque
alpine landscape, killed almost 60 people and
sent ash for hundreds of miles. The force of the
eruption coated eastern Washington with a thick
layer of light gray ash. When wet the ash became
as dense as cement making it hard to remove from
lawns, roofs and roads. The ash can still be seen
along I-90 and elsewhere in the area. Parts of
Idaho and Montana had deposits as the ash was
caught up in the jetstream winds. The blast
removed 1000 feet off the top of the mountain,
leveled 200 square miles of forest to the north,
moved Spirit Lake and formed new lakes. The sound
of the explosion could be heard as far away as
Canada. Giant mudflows raced down the mountain
into local rivers destroying bridges, vehicles
and houses. The sound of the explosion could be
heard as far away as Canada. Mount St. Helens is
one of the Cascade Volcanoes that reach from
Washington to California.
16events
- glowing avalanches or nueé ardente is a hot
(700-1000 degree C) ash-laden gas cloud - moves at extremely fast speed (average of 160
km/hr) down the volcano slope - rock formed by this is called ignimbrite or
welded tuff
17events
- lava flows type of flow depends on viscosity
which is related to silica content - stiff, highly viscous silica rich lava flows in
blocks and forms a blocky surface on the lava
called aa texture - fluid, less viscous, lower silica lava flows in
rope like surface called pahoehoe texture - Hawaiian names
18events
- Volcanic mudflows (lahars)
- pyroclastic material mixed with water that flows
rapidly (10 m/s)
19tsunamis
- great sea waves caused by the displacement of
water due to a sub oceanic volcanic eruption or
earthquake - great velocities up to 5 000 km / hr
- as they reach the shore they rise up into giant
waves that flow in over the land
20tsunami
21tsunami
22tsunami
23tsunami
24tsunami
25Volcanic rocks
- Pyroclastic rocks - molten material is ejected
and solidifies in the air - classified as sedimentary rocks
26particles in volcanic rocks
- preexisting rock particles are blocks gt64 mm,
or lapilli 2-64 mm, - molten lava which cools are bombs gt 64 mm,
ash-silt size
27pyroclastic rock names
- Ash tuff - rock predominated by ash sometimes
simply referred to as tuff. - Lapilli tuff - rock predominated by lapilli.
- Tuff breccia - rock containing 25 to 75 blocks
and/or bombs. - Pyroclastic breccia - rock containing at least
75 blocks and bombs. - Agglomerate - rock containing at least 75 bombs.
- Agglutinate - rock composed of fused, largely
unrecognizable, basalt spatter fragments.
28pyroclastic rock names
- pumice or scoria has numerous gas holes
- obsidian is volcanic glass which cooled suddenly
- bentonite pure montmorillonite clay formed from
weathered ash
29volcanic flow rock names
- in order of increasing silica (downwards) and
increasing explosiveness - basalt
- andesite
- dacite
- latite
- rhyolite
30volcanic flow rock names
- in order of increasing silica (downwards) and
increasing explosiveness - basalt
- andesite
- dacite
- latite
- rhyolite
31volcanic flow rock names
- in order of increasing silica (downwards) and
increasing explosiveness - basalt
- andesite
- dacite
- latite
- rhyolite
32volcanic flow rock names
- in order of increasing silica (downwards) and
increasing explosiveness - basalt
- andesite
- dacite
- latite
- rhyolite
33Volcanic rock terms
- aphanitic fine grains that are not visible to
the eye - phenocrysts large crystals in the aphenitic
matrix - traprock light colour aphanitic volcanic rock
- felsite dark colour aphanitic volcanic rock
- vesicles holes in the rock formed by gas
bubbles - vesicular rocks with numerous vesicles
- scoriaceous vesicular and extremely porous
- amygdule mineral that fills the vesicle
- amygdaloida a rock with numerous vesicles
filled with minerals
34Volcanic rock terms
- aphanitic fine grains that are not visible to
the eye - phenocrysts large crystals in the aphenitic
matrix - traprock light colour aphanitic volcanic rock
- felsite dark colour aphanitic volcanic rock
- vesicles holes in the rock formed by gas
bubbles - vesicular rocks with numerous vesicles
- scoriaceous vesicular and extremely porous
- amygdule mineral that fills the vesicle
- amygdaloida a rock with numerous vesicles
filled with minerals
35Volcanic rock terms
- aphanitic fine grains that are not visible to
the eye - phenocrysts large crystals in the aphenitic
matrix - traprock light colour aphanitic volcanic rock
- felsite dark colour aphanitic volcanic rock
- vesicles holes in the rock formed by gas
bubbles - vesicular rocks with numerous vesicles
- scoriaceous vesicular and extremely porous
- amygdule mineral that fills the vesicle
- amygdaloidal a rock with numerous vesicles
filled with minerals
36Volcanic rock terms
- aphanitic fine grains that are not visible to
the eye - phenocrysts large crystals in the aphenitic
matrix - traprock light colour aphanitic volcanic rock
- felsite dark colour aphanitic volcanic rock
- vesicles holes in the rock formed by gas
bubbles - vesicular rocks with numerous vesicles
- scoriaceous vesicular and extremely porous
- amygdule mineral that fills the vesicle
- amygdaloidal a rock with numerous vesicles
filled with minerals
37Volcanic rock terms
- aphanitic fine grains that are not visible to
the eye - phenocrysts large crystals in the aphenitic
matrix - traprock light colour aphanitic volcanic rock
- felsite dark colour aphanitic volcanic rock
- vesicles holes in the rock formed by gas
bubbles - vesicular rocks with numerous vesicles
- scoriaceous vesicular and extremely porous
- amygdule mineral that fills the vesicle
- amygdaloidal a rock with numerous vesicles
filled with minerals
38Volcanic rock-mass characteristics
- complex in composition, flows, pyroclastic debris
etc. and interbeds of non volcanics - flows follow lows in the topography
- resistant to weathering after a long period of
physical weathering the deposits which once were
in the bottoms of valleys form tops of mountains,
table mountains - irregular lateral extents
39Volcanic rock-mass characteristics
- complex in composition, flows, pyroclastic debris
etc. and interbeds of non volcanics - flows follow lows in the topography
- resistant to weathering after a long period of
physical weathering the deposits which once were
in the bottoms of valleys form tops of mountains,
table mountains - irregular lateral extents
40Volcanic rock-mass characteristics
- complex in composition, flows, pyroclastic debris
etc. and interbeds of non volcanics - flows follow lows in the topography
- resistant to weathering after a long period of
physical weathering the deposits which once were
in the bottoms of valleys form tops of mountains,
table mountains - irregular lateral extents
41Volcanic rock-mass characteristics
- complex in composition, flows, pyroclastic debris
etc. and interbeds of non volcanics - flows follow lows in the topography
- resistant to weathering after a long period of
physical weathering the deposits which once were
in the bottoms of valleys form tops of mountains,
table mountains - irregular lateral extents
42fractures and permeability
43Weathering products
- contrasting potential for weathering - basalt is
more basic than granite and thus more inclined to
decay due to chemical weathering - on one hand the rocks are often impermeable in
themselves which would deter chemical weathering - on the other there are often numerous joint which
make the rock mass on a whole very permeable,
enhancing chemical weathering - young basalt often is not weathered, but old
basalt is deeply decomposed to a clay soil,
expansive montmorillonite
44Engineering problems with volcanism and volcanic
rocks
- Enormous damage potential!!
- ash fall risks
- abrasive
- clogs drains
- poisonous
- causes fires
- weight can damage structures (like water logged
snow)
45Engineering problems with volcanism and volcanic
rocks
- Enormous damage potential!!
- lava flow risks
- flow relative slow
- diversion possible trenches, barriers and
spraying with cold water can be used to deter the
flow - predict flow path possible
46Engineering problems with volcanism and volcanic
rocks
- Enormous damage potential!!
- mudflow risks
- huge quantity
- high velocities
- path predictable far in advance but the velocity
and size of the flow makes it difficult to
contain, dams are easily broken, barriers jumped - preparatory measures can be taken, lower the
level of water reservoirs
47Exploration and volcanic rocks
- complexity of the deposits makes it difficult to
predict their vertical and lateral extent - stratigraphy can vary greatly laterally
- marker layers are needed
- need to find the extent of the material with
lower strength and high permeability
48 Surface excavation
- excavation often requires blasting
- blocks often displaced on slopes float in soft
materials (fig 7.18)
49Underground excavations
- Difficulty can be represented by two cases
- it took 6 years to tunnel 17 km
- two years to tunnel 263 m
50Underground excavations
- large water inflow is common due to the
- open fractures and joint
- highly permeable layers
- permeable interbeds
- folded beds can entrap water in compartments
51Underground excavations
- hard and dense if unweathered too hard for a
tunnel machine - large extent of jointing results in high
potential for rock fall shortcrete required - horizontal stress ? zero, vertical stress
weight of the overlying rocks thus there is a
high potential for the roof to collapse
52Underground excavations
- active areas poisonous gas can occur
- young areas non cemented rock common
- warm water flows can occur
53Dams and canals
- leakage is a great problem grouting is required
- compressibility high bearing capacity poor
- shear strength low slides probable
54Dams and canals
- Hoover dam Fig 7.22, height 222 m
- founded on volcanic breccia
- grout curtain depth originally to be 40 m ended
up 130 m deep and horizontally 90 m
55Dam in Sardinia
- rock fill dam
- concrete face
- founded on a series of lava flows with columnar
jointing and tuff beds - serious differential settling
- fault under dam
56Engineering materials
- volcanic rocks are used in all aspects of
engineering - aggregates
- concrete
- asphalt
- rock fill
- dams
- breakwaters
- coarse grade
- dimension stone
- Note there are some things to look out for
57Problems as engineering material
- volcanic glass reacts with alkalies in Portland
cement cracking of the structure - amygdules that are often filled with the
following minerals opal, zeolite, gypsum these
are not good in concrete, reactive - pillow lava has often an unstable rind which is
reactive with Portland cement - weathering can be rapid for some rocks X ten
years sand and gravel - disintegration tests should be made to test the
life expectancy of the rock (top p.286)
58Case studies
- Protection of an Icelandic port from volcanism
barriers were erected and seawater pumped onto
the flow to cool it
59Case studies
60Case studies
- Round Butte Dam, Oregon
- 133m high dam in lava flows with interbeds of
non-volcanics. Fig 7.25 - Several layers required grouting
- In all 42 km of grout holes were filled with 4000
m3 of Portland cement grout and took two years to
carryout