Transcript ppt file2
Magma
Explosive
activity
Effusive
activity
Hawaiian
Strombolian
Vulcanian
Peleean
Plinian
Surtseyan
Fluid
Moderately
fluid
Viscous
Viscous
Viscous
Viscous
Fountains,
low
eruption
columns
Weak to
violent
ejection
Moderate
to violent
ejection of
solids
Ejections
of solids,
nuee
ardents
Sudden
ejection of
ash
Violent
ejections
Thin,
extensive
flows
Thick, nonextensive
lava
Flows
commonly
absent
Domes
Ash flows
Pillowed
lava flows
Blocks and
ash,
pumice,
bombs
Lithic
ejecta,
blocks and
ash,
pumice
Glassy
ash and
pumice
Block and
ash,
accretionary
lapilli
Ash cones
Domes,
spines
Ash beds
Tuff rings
Dominant
ejecta
Bombs
Bombs,
cinders, vitric
ash
Structures
Lava
lakes and
cones
Cinder
cones
More Fluid --> Hotter + Easier gas release (less explosive) + Less siliceous
Eruption Products
Eruption products
Lava types
Basaltic
- Pahohoe
- A’a
- Pillows
Andesitic
- Blocky
Rhyolitic
-Pyroclasts
-Pyroclastic rocks
-Pyroclastic deposits
In general
Molten rock (magma) that pours or oozes onto the
Earth's surface is called lava. The higher a lava's
silica content, the more viscous it becomes.
For example, low-silica basalt lava can form fastmoving (10-30 miles per hour), narrow lava
streams or spread out in broad sheets up to
several miles wide. In contrast, higher-silica
andesite and dacite lava flows tend to be thick,
move slowly, and travel short distances from a
vent.
Basaltic lava
Erupt primarily from fissure systems and shield
volcanoes (eg., Hawaii).
These fluid lava flows can be subdivided into two types,
based primarily on the nature of lava flow surfaces:
Pahoehoe Lava -- (pa-hoy-hoy) Hawaiian for
“smooth, ropy lava”.
Aa lava -- Hawaiian for “rocky lava”.
The lava is identical in both pahoehoe and aa lava flows,
the difference comes from the amount of lava erupted
and the speed of cooling.
Basaltic lava
Lobes
Pahoehoe Lava -- Hawaiian for “smooth, ropy lava”. Surfaces
are smooth, billowy, or ropy. Formed from less viscous lava that
advances slowly. Forms as the outer layer of the lava cools, then
is dragged and folded as the flow continues to move beneath the
surface.
Basaltic lava
Aa lava -- Hawaiian for “rocky lava”. Surfaces are fragmented,
rough, and spiny, with a "cindery" appearance. Forms when lava
initially flows rapidly resulting in heat loss and an increase in
viscosity.As the flow continues to move, the surface layer is
broken into jagged pieces.
Basaltic lava
Pahoehoe is common near the source of a basaltic flow,
where the lava is hottest, and aa is normally found farther
from the source, where the lava has cooled off significantly.
Basaltic lava
Intermediate basaltic lava flow
with characters of both Aa and
Pahoehoe on Etna – Sept. 2004
Photograph GS -
Basaltic lava
Important note: Pahoehoe flows cannot turn into
aa flows, and vice versa.
For example, pahoehoe flows cannot evolve from
lava already erupted with an aa surface. The new
lava has to come from deep within the parent flow
and has a separate crystallization history.
Basaltic lava
Pillow lava -- when lava is erupted under water or ice. As lava is
extruded, the water (or ice) quickly chills the outer layer. Molten
lava beneath the chilled surface eventually breaks through the skin
and the process is repeated, resulting in a pile of lava pillows
Convex upward tops
Cusped bottoms filling space
Cross section of pillow basalts
Basaltic lava tubes
These require Pahoehoe lava
which has the correct
thickness to form a crust/tube
from the inside of which the
still-molten lava then pours
out. Roof collapses frequently
allow access to these caves.
Achilles with shield
Basaltic lava
Slow build up of fluid lava flows produces shield
volcanoes as lava pours out in all directions from a
central summit vent, or group of vents, building a broad,
gently sloping cone of flat, domical shape, with a profile
much like that a a warrior's shield.
Basaltic lava
Mauna Loa on the island of Hawaii
Andesitic lava
Andesite generally produces blocky lava that advances only short
distances down the flanks of a volcano. Resembles aa flows, but more
regular shaped polyhedral chunks rather than jagged, vesicular,
scoriaceous deposits.
Bagana volcano, Bougainville Is, P.N.G. 26-April-1988
Rhyolitic lava
Pyroclasts
Pyroclastic rocks
Pyroclastic deposits
Tephra and pyroclasts
Tephra (Greek, for ash) is a generic term for
unconsolidated, air-fall material produced by a volcanic
eruption regardless of composition or fragment size.
“Pyroclasts are the individual crystals, crystal
fragments, glass and rock fragments generated by
disruption as a direct result of volcanic action.” (Schmid,
1981)
A pyroclastic rock is produced from the consolidation of
pyroclastic accumulations into a coherent rock type.
Pyroclasts
Ash -- Very fine-grained fragments (< 2 mm), generally dominated
by broken glass shards, but with variable amounts of broken crystal
and lithic (rock) fragments.
Pyroclasts
Lapilli-- Pea (cinders)- to walnut-size pyroclasts (2 to 64 mm). In
water-rich eruptions, the accretion of wet ash may form rounded
spheres known as accretionary lapilli.
Pyroclasts
Blocks and Bombs -- Fragments >64 mm. Bombs are ejected as
incandescent lava fragments which were semi-molten when airborne,
thus inheriting streamlined, aerodynamic shapes. Blocks are ejected as
solid fragments with angular shapes.
Pyroclasts
Pyroclastic textures
Within this size classification, specific
types of pyroclasts can be further defined
by physical attributes
A little controversial
Pyroclastic textures
Lapilli-size fragments of basaltic lava may cool quickly while
airborne, to form glassy teardrop-shaped lapilli called Pele's tears.
During strong winds (in fire fountains), these molten fragments can
be drawn out into fine filaments called Pele's hair.
(Pele is the Hawaiian fire goddess of volcanoes).
Pyroclastic textures
Non-explosive eruptions often produce lapilli- to bomb-size
fragments, called spatter which remain airborne for only a short
amount of time so that are still liquid when they hit the ground
surface.
Pyroclastic textures
Vigorous gas escape in felsic lavas produces pumice, a very light
colored, frothy volcanic rock texture made of glass.
The lava is ejected and shot through the air during an eruption. As
the lava hurtles through the air it cools and the gases escape
leaving the rock full of holes.
Pumice is so light that it actually floats on water.
Pyroclastic textures
Similar gas escape in mafic lavas produces reticulite.
Reticulite has a lower density than pumice, with vesicles occupying
up to 98% of the total volume. Unlike pumice, however, most of the
bubble walls in reticulite are broken so that it sinks in the presence of
water.
Pyroclastic textures
Reticulite, however, is not as common as scoria, a denser mafic
rock texture containing a smaller abundance of relatively large
vesicles.
Brittle
Vesicularity: 70-85% Crystallinity: 2-50%
Pyroclastic Rocks
Classification of the pyroclastic rocks.
a. Based on type of material.
b. Based on the size of the material. After Fisher (1966) Earth Sci. Rev., 1, 287-298.
Pyroclastic deposits
Pyroclastic FALL deposits
Relate to magma chamber geometry, discharge rate etc.
Derived from Plinian eruptions where they fall out of the
eruption plume
The deposit is composed of highly vesiculated dacitic to
rhyolitic pyroclasts which can be distributed for hundreds of
square kilometers away from the vent.
Larger bombs deposited near the vent, smaller ash and lapilli
and pumice further away.
Pyroclastic deposits
Pyroclastic SURGE deposits
Dilute mixture of gas and ash (similar to pyroclastic flows) but are
mostly gas.
Turbulent suspension results in wavy-, lenticular- or low angle cross
bedding .
Richer in crystals and lithics than pyroclastic flows and are better
sorted.
Pyroclastic deposits
Pyroclastic FLOW deposits
Nuee Ardents (Peleean activity) -- these contain dense lava fragments
derived from the collapse of a growing lava dome or dome flow
Non vesiculated block fragments suspended in ash (block and ash
flows)
Pumice flows (ignimbrites) -- these contain vesiculated, low-density
pumice derived from the collapse of an eruption column.
Vesiculated, pumice-dominated with subordinate ash
Pyroclastic deposits
Stratovolcanoes show inter-layering of lava flows and pyroclastic
material, which is why they are sometimes called composite
volcanoes. Pyroclastic material can make up over 50% of the
volume of a stratovolcano.
Have steeper slopes than shield volcanoes, with slopes of 6 to 10
degrees low on the flanks to 30 degrees near the top.
Pyroclastic deposits
Mount Ngauruhoe, New Zealand
61 eruptions since 1839
Mount Doom, Mordor
Pyroclastic deposits
Tephra (or cinder) cones are small volume cones consisting
predominantly of tephra that result from strombolian eruptions. They
usually consist of basaltic to andesitic material and are actually fall
deposits that are built surrounding the eruptive vent.
Slopes of the cones are controlled by the angle of repose (angle of
stable slope for loose unconsolidated material) and are usually
between about 25 and 35 degrees.
Pyroclastic deposits
SP Crater, in the San Francisco Volcanic Field
Pyroclastic deposits
Volcanic domes are masses of solid rock that are formed when
viscous lava is erupted slowly from a vent.
Most domes are short-lived features, because they are commonly
destroyed by collapse partly due to volcanic explosions and due to
strains set during cooling. The speed of dome growth varies
considerably, but some rise by as much as 25 m/day.
Pyroclastic deposits
Mt St. Helens
Pyroclastic deposits
Lava flow
Ash fall deposit
Pumice clast
Ignimbrite (10-100m)
Lithic clast
Plinian fall deposit (1m)
Eruption products
Basaltic lava flows and deposits
Andesitic flows
Rhyolitic pyroclasts, pyroclastic rocks and
pyroclastic deposits
Used to interpret volcanic history of a
region.
Lecture ppt file:
my web page:
www.zolfo78.com/lectures or
http://people.stfx.ca/gsolferi/
Wanna visit Italian
volcanoes?
Send me an e-mail
for advice:
[email protected]
Hornito structure –
Etna Sept. 2004