Today for episode 381, we’re going to Zealandia. No, it’s not a quirky
TV show modeled after Portlandia. It’s the 7th largest continent on
earth.
We’re not talking continents in the geographic sense, really
large land masses like Africa and South America, but we are talking about
continental material in the geologic sense, even though most of it is submerged
beneath the ocean.
 |
| Public Domain via Wikipedia |
Although the ocean floor around the globe is diverse, with
seamounts and trenches, fault zones and piles of volcanic rocks here and there,
on the whole oceanic crust is deep and uniform, or at least varying broadly and
predictably. These relatively small-scale high plateaus on the ocean floor
around New Zealand are unusual.
Let’s define a continent. Geographically, it usually means a
large land mass. “Large” is subjective, but Australia, at about 9 million
square kilometers, is considered to be the smallest continent. And the count
depends on whether you separate Europe from Asia, or just say Eurasia as one,
and other conventions. Many would say that a degree of isolation and separation
also defines a continent, so Eurasia should be one, together with Africa, North
America, South America, Antarctica, and Australia, for a total of six. Forget
all that. We’re looking at places made of continental crust, the generally
lighter, silica-rich material in contrast to oceanic crust, denser and more
iron-rich.
By that geologic definition, all the conventional continents
really are mostly continental crust too. All well and good. There are numerous
smaller, separated areas of continental crust that are usually called
microcontinents. Madagascar is probably the best example of a microcontinent,
but there are lots of them, and you can get into plenty of arguments about
whether a piece like, say, Greenland, is or is not fully a part of the North
American continent.
So, let’s go to Zealandia. In 2017, Nick Mortimer and colleagues,
writing in GSA Today, pretty much laid any argument to rest. There’s abundant
evidence to say that there is a large, diverse terrain centered on New Zealand
but 94% submerged, that is mostly continental crust. It adds up to about 5
million square kilometers, comparable in size to Arabia and India,
sub-continents that are connected in one way or another with full-fledged
continents. Zealandia is close to, but clearly separated from Australia, and
Mortimer and others make a convincing case that it should be considered the
seventh continent, six times larger than Madagascar, the biggest
microcontinent.
So if continental rocks are lighter, which accounts for them
being for the most part above sea level, why is most of Zealandia under water?
The crust there is thinner, so it doesn’t rise as high as that on most
continents, and it has been stretched and broken, partly rifted apart during a
long complex history.
Zealandia was probably originally part of the supercontinent
of Gondwana, attached to eastern Australia and West Antarctica, when those two
continents were fully attached to each other about 105 million years ago, in
Early Cretaceous time. That margin of Gondwana, thousands of kilometers long,
was a subduction zone somewhat like today’s Andes, with an old Pacific oceanic
plate diving beneath the Gondwana continental crust. There would have been a
volcanic mountain range there, recorded in Zealandia as a surviving string of
granitic rocks, batholiths similar to those that developed in western North and
South America during Mesozoic and Cenozoic time and continuing to this day.
Gondwana began to be rifted apart by about 85 million years
ago, Late Cretaceous time. It appears that one of the first parts to go from
this part of the supercontinent was what is now Zealandia, a long narrow ribbon
along the coast of the continent. Australia and Antarctica probably began to
separate at about the same time, but that was initially a rather slow break-up
that wasn’t complete for close to fifty million years.
The idea of a long narrow ribbon of continental crust
rifting off a continent has plenty of precedents. During the Ordovician, the Avalonian ribbon
rifted away from what is now northwest Africa and ultimately collided with
North America, where it forms parts of Newfoundland, Nova Scotia, and New
England today. More recently, a string of continental fragments rifted off what
is now eastern Arabia and Africa, to collide with Eurasia to form the cores of
Turkey, Iran and Afghanistan today. It’s also possible that one or more “ribbon”
continents broke off what is now northern India, to begin to amalgamate with
Eurasia in today’s Himalayas, even before India itself collided.
The rifting that split Zealandia off Gondwana is recorded in
sedimentary rocks. The initial rifting may have begun the crustal thinning and
breaking of Zealandia that we see today, but some of that may have developed
later. Because Zealandia was (and is) in a zone of complex interactions among
small and large continental and oceanic plates, it’s not really surprising that
it would have undergone quite a bit of tectonic and crustal modification.
Today, the main part of Zealandia that’s above sea level, New Zealand, contains
the Alpine Fault, a huge strike-slip fault similar to the San Andreas. The Alpine
Fault is ripping Zealandia apart, but even that helps us recognize Zealandia as
a small continent. Mortimer and his colleagues identified rock types in the sea
floor on both sides of the Alpine Fault – rock types that can be correlated
with each other, and that reflect the predicted offsets you’d expect from the
Alpine Fault.
I think Mortimer and his colleagues have made the case quite
convincingly that we should indeed think of Zealandia as a continent,
geologically speaking, even though most of it is under water.
Book, Zealandia:Our Continent Revealed, published in 2014.
—Richard I. Gibson
No comments:
Post a Comment