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HAWAIIAN LAVA FLOWS

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Title: HAWAIIAN LAVA FLOWS


1
HAWAIIAN LAVA FLOWS
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From Hawaiian Dictionary by M.K. Pukui S.H.
Elbert
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(Courtesy of Ululani Makue)
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-low volumetric flow rate (lt10 m3 s-1) -low
flow-front velocity (1-10 m hr-1) -develops
lava tubes -innumerable flow units -thin (10-100
cm) flow units -lower viscosity -lower yield
strength -slightly hotter -helluhraun (pavement
lava) in Icelandic
-high volumetric flow rate (10-103 m3
s-1) -high flow-front velocity (102-104 m
hr-1) -develops large channels -few, large flow
units -thick (1-10 m) flow units -higher
viscosity -higher yield strength -slightly
cooler -apaluhraun (rough lava) in Icelandic
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3 m
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Wave-cut cliff section, Makapuu, Oahu
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For every lava rheology, there is a critical
disruption rate beyond which it cannot flow as a
fluid
Qualitative graph after Peterson Tilling (1980)
and Kilburn (1981)
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When moving, the incandescent interior is deforms
fluidly
1 m
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The top surface consists of relatively small,
spiny clinkers
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standard geologists for scale
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5 m
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A big, fast-moving channel (1984 Mauna Loa
eruption)
10 m
flow direction
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Channels develop downflow, from distinct near the
vent to indistinct (or non-existent) at the flow
front.
flow front
flow direction
stable channel
Lipman Banks (1987)
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A velocity gradient sets up relative rotation and
shear, tearing viscous lumps of surface and
near-surface lava into ragged clinkers.
20
Air photo of the distal end of the 1942 Mauna Loa
flow
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Transition of distinct channel to zone of
dispersed flow
4 m
flow direction
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flow cores
clinker
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Accretionary lava balls
1.5 m diameter
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0.5 m
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2 m
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40 cm
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20 cm
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Inflated flows exposed at the coastline of Pinta,
Galápagos
pelican for scale
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Multiple generations of ropes
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Side view into an active lava tube
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a 1 m x 2 m skylight in the roof of an active
tube
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Master lava tubes can be many meters high and
wide. Note that during a tube-fed eruption, the
main tube is essentially as long as the flow,
(the distance from vent to flow- front), but
afterwards it almost never drains completely.
38
Like a large channel, a large tube develops
downflow
(same time, different locations along the flow)
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One mechanism of tube formation is coalescence of
many small, single flow-unit tubes (i.e., toes)
into a master tube.
(same location, different times)
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Another tube-formation mechanism is roofing of a
lava channel. Here, the surface skin is growing
in a down-flow direction.
flow direction
1 m
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Here, a surface skin growing inward from the
channel margins
1 m
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Sources of blue fume mark the line of an active
tube
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Tumulus on 1859 Mauna Loa flow, on the coastal
plain
George Walker for scale
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Tumulus on an old Mauna Loa SW rift zone
flow, Puu Hou (1868 littoral cone) in background
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A leaky tumulus
2 m
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10 cm
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s
p
p
p
s
s
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Water inhibits formation of this secondary
coating -it does not form near water- retaining
fractures -it does not form where rain drips
from plants -shading of sunlight is also involved
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Lava trees (2 m high)
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A forest of lava trees, partially buried by scoria
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PAU
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