We
have some interesting examples of continental rifts in the world, as
well as spreading ridges in oceanic crust – and since these are
both examples of diverging boundaries, geologists are justified in
assuming that similar processes are involved in rifting. But that's
a hypothesis. Observations of the process of rifting in the real
world are revealing that continental rifts are more complicated.
One
reason may be that oceanic crust is denser, but thinner than
continental crust. The difference between them is demonstrated when
the two types of crust are driven together. Continental crust is fat
and buoyant, so the immense pressure pushes the thinner, denser
oceanic crust beneath the continental crust (subduction). Water
vapor that subducts with the oceanic crust allows it to melt at lower
temperatures than it normally would, and the partially melted stuff rises through the continental crust above the subducting slab.
As it rises, the reduced pressure allows it to melt further, where it
also melts some of the surrounding continental rocks. It may pool
between sedimentary layers, forming plutons, sills, and dikes that
cool underground, or it may extrude onto the surface and form
volcanoes. That's what can happen at a converging zone. But at the
other end of that zone is a rift.
Oceanic
rifts are ongoing projects – upwelling convection currents in the
mantle inflate and stretch the crust above, causing fractures.
Magma squeezes through fractures, forcing the crust apart even
further, and forming spreading ridges. You might think that the
magma would cool and plug the holes – something that happens quite
often when magma extrudes onto continents. But the plug is temporary. The centers of those new dikes are weak, and they fracture from the pressure of the uprising heat, allowing more low-silica magma to flow into the new fracture.
Silica
is sticky stuff. Magma with a higher silica content is less runny.
At oceanic rifts, the runny, lower-silica magma is a lot less likely
to clog up the dikes and vents through which it is welling. That
low-silica magma actually cools at higher temperatures, and water is
present to speed that cooling. But when magma cools, it shrinks, and
fresh hot stuff can well up around it, gradually forcing the rift
zone apart. You can actually observe the whole,
extrude-shrink-extrude-again process in the nifty pillow lavas that
form around oceanic volcanoes as magma hits the water, instantly cooling
to form a shell, which bursts at its weakest point and forms a new
blob when more molten rock is forced into it. (If there was a cable
channel just for watching pillow lavas form, I would sign up for it.)
Oceanic
rift zones seem to last as long as the upwelling convection currents
that drive them (a phenomenon called slab pull
may also be involved, with the weight of the dense continental crust
being subducted into the mantle possibly pulling the plate from the
other end). But continental rift zones may require more oomph to
keep them going.
This
oomph could be a mantle plume (as is the case with the caldera below
Yellowstone), or an upward convection current combined
with a mantle plume (as is the case with the rift zone in Iceland.)
But Yellowstone is considered a supervolcano rather than a rift zone,
and Iceland is a comparatively small chunk of continental rock.
There's a continental rift under way in Colorado and New Mexico, but
it's pretty low key when compared with the poster child of
continental rifts, The African Rift.
Theoretically,
the African Rift is doing the same thing that the Arabian Gulf is
doing, forming a basin as the crust spreads apart that will
eventually open up to form a new sea. The Atlantic Ocean formed that
way when Pangea broke apart. Since spreading ridges in oceans are
faulted all the way down to the mantle, you could expect that a
continental rift would also have faults that run that deep. Evidence
for that can be found in low-silica volcanic rocks in the Southwest
U.S. Arizona even has a shield volcano, the sort of volcano one
would usually expect to find above a mantle plume forming an island
chain (like Hawaii). Yet the volcanoes along the U.S. Rift are not
all of this type. Likewise, the volcanoes that have formed along the
sides of the rift zone in Africa are a grab bag of different types,
anything from volcanic vents and relatively flat volcanoes, to giant
composites like Kilimanjaro.
What
this suggests is that sometimes low-silica magma is reaching the
surface along these rifts (often creating extensive sills and dikes
along the way), and sometimes it's mixing with the continental rocks
it encounters on its upward journey and melting that stuff,
introducing more silica into the mix and building composite cones at
the surface, or cinder cones, or volcanic domes, or even creating
plutons that cool underground.
Besides
the silica ratio, another thing that determines the size, shape, and
explosiveness of volcanic features is the amount of volatiles in the
mix – gases. High silica/low gas mixes produce volcanic domes that
extrude almost like toothpaste. Low silica/high gas mixes produce
cinder cones. An intermediate mix can produce a composite volcano,
like the one above Flagstaff, Arizona (far inland from where you
would expect to find such a structure). The super-volcanoes of the
Western U.S., Yellowstone and the Valles Caldera, are very
high-silica caldera volcanoes that fractured the crust overlying them
with expansion caused by heat, which allowed gases to escape through
the cracks, widening them further and causing a collapse.
The collapse of that surface material into the caldera produced titanic explosions. The rhyolitic tuff (fused ash) of
Bandelier National Monument in New Mexico was created by an explosion
from the Valles Caldera. Compare all that complicated stuff to good
ol'oceanic rifting, and it just seems like such a straight-forward
process in comparison.
Continental
rifts seem like a lot more work. Maybe that's why continental rifts
sometimes seem to just stop. The rifting had some oomph when it
started out, but the upwelling current shifted, or the plume stopped,
or the older part of the craton, where the crust is too thick to be
rifted, moved over the whole bubbling mess. (The tectonic plates,
including continents, move gradually but steadily over the upper
mantle.)
One
failed rift is the North American Mid-Continental Rift (extending
from Lake Superior to Oklahoma), which seems to have pooped out about
a billion years ago. At that time, we were part of the
supercontinent Rodinia, which split up about 750 million years ago.
Two other supercontinents formed and broke apart after that.
Eventually, North America will collide with Asia, and the rifting
will start somewhere else.
But
regardless of what happens in the future, the African Rift is
happening right now, in some ways that were predicted, and in some
ways that were not. It will continue to be a fascinating example of
what happens when continents are pulled apart.
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