This is what Earth will look like in 100,000,000 AD
To map the supercontinent of the future, geologists first had to
solve a vexing magnetic riddle.
Earth's modern continents are the fragments of a single,
300-million-year-old supercontinent called Pangaea.
This vast landmass once rested on the equator, near where Africa is
today.
During the age of dinosaurs, tectonic forces slowly tore Pangaea
apart. Now geologists predict those same forces will reassemble the
pieces into a new supercontinent, named Amasia, about 100 million years
in the future.
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Most of today's continents (left) will
migrate toward the North Pole and collide to
form a new landmass called Amasia (right). |
Ancient rocks and mountain ranges show that the constant movement of
Earth's crust has assembled and ripped apart supercontinents several
times before, in a roughly half-billion-year cycle. But pinpointing
where the past ones formed has proven difficult, which in turn clouded
attempts to forecast the next great smashup.
A team of Yale geologists say they have cracked the problem,
providing the best look yet at the planet of a.d. 100,000,000. Led by
graduate student Ross Mitchell, the researchers first looked back beyond
Pangaea and determined the location of supercontinents Rodinia, which
formed about a billion years earlier, and Nuna, 700 million years before
that.
The team found that during the past two cycles, each supercontinent
formed a quarter of the way around the globe from where the previous
supercontinent had been. Using that insight, they calculated that Amasia
will form over the North Pole.
Their prediction is based on a new method of interpreting data from
magnetic traces found in ancient rock samples. Those traces, which
record the orientation of the samples relative to Earth's magnetic field
when they solidified, can be used to determine where on the globe the
rocks formed.
Geologists can then use those data to track the supercontinents'
movements.Magnetic traces have long been used to calculate the
latitudes, the north-south positions, of ancient continents.
But longitude, the east-west position, is much trickier to pin down
because Earth's magnetic field varies little with longitude.
To overcome the problem, Mitchell and his team devised a new way of
analysing the magnetic data to detect a phenomenon known as true polar
wander - the gradual change in the position of Earth's poles as the
planet's internal mass shifts. By tracking polar wander through time,
the researchers were able to determine the longitudinal position of
ancient rocks. "This is the first time there's
been a method to capture information on paleolongitude," says Brendan
Murphy, a geologist and plate tectonics expert at St. Francis Xavier
University in Nova Scotia.
The findings offer more than a glimpse into the world of tomorrow.
A better understanding of the supercontinent cycles will shed light
on the evolution and dispersal of the prehistoric creatures that were
passengers on these travelling continents.
The discovery also has implications for the search for oil, which
usually forms where continents drift apart, says Mitchell, a consultant
for Shell.
- Discover Magazine
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