A
team of international scientists are planning to drill into the
Earth's mantle in an attempt to answer questions about the origins and
evolution of life. The drills will need to get through around 6 km of
oceanic crust to reach the mantle.
Mission impossible?
- Scientists planning mission to drill down to Earth's mantle and bring back first fresh samples
- Mantle could hold clues to origin and evolution of the planet
- Geologist calls it the most "challenging endeavor in the history of Earth science"
- If project gets the go-ahead, the team hope to reach the mantle by early 2020s
This may be about to
change with a $1 billion mission to drill 6 km (3.7 miles) beneath the
seafloor to reach the Earth's mantle -- a 3000 km-thick layer of
slowly deforming rock between the crust and the core which makes up
the majority of our planet -- and bring back the first ever fresh
samples.
It could help answer some
of our biggest questions about the origins and evolution of Earth
itself, with almost all of the sea floor and continents that make up the
Earth´s surface originating from the mantle.
Geologists involved in
the project are already comparing it to the Apollo Moon missions in
terms of the value of the samples it could yield.
However, in order to
reach those samples, the team of international scientists must first
find a way to grind their way through ultra-hard rocks with 10 km-long
(6.2 miles) drill pipes -- a technical challenge that one of the project
co-leaders Damon Teagle, from the UK's University of Southampton
calls, "the most challenging endeavor in the history of Earth science."
"It will be the equivalent of dangling a steel string the width of a
human hair in the deep end of a swimming pool and inserting it into a
thimble 1/10 mm wide
Damon Teagle, University of Southampton, UK
Damon Teagle, University of Southampton, UK
Their task will be all
the more difficult for being conducted out in the middle of the ocean.
It is here that the Earth´s crust is at its thinnest at around 6 km
compared to as much as 60 km (37.3 miles) on land.
They have already
identified three possible locations -- all in the Pacific Ocean -- where
the ocean floor was formed at relatively fast spreading mid-ocean
ridges, says Teagle.
The hole they will drill
will be just 30 cm in width all the way from the ocean floor to inside
the mantle -- a monumental engineering feat.
"It will be the
equivalent of dangling a steel string the width of a human hair in the
deep end of a swimming pool and inserting it into a thimble 1/10 mm wide
on the bottom, and then drilling a few meters into the foundations,"
says Teagle.
To get to the mantle
scientists will be relying on a purpose-built Japanese deep-sea drilling
vessel called Chikyu, first launched in 2002 and capable of carrying
10 km of drilling pipes. It has already set a world-record for the
deepest hole in scientific ocean drilling history, reaching 2.2 km into
the seafloor.
What makes the task even
more difficult is that, currently, the drill bits have a limited
lifespan of between 50-60 hours before needing to be replaced, meaning
drilling could take many years unless technology improves.
The first attempts to
reach the Earth's mantle actually began back in the early 1960s. Dubbed
"Project Mohole" after the Croatian meteorologist Andrija Mohorovicic
who first discovered the boundary between the Earth's crust and mantle, a
team of U.S. scientists managed to drill a few meters into the oceanic
crust off Guadalupe Island in the eastern pacific. The achievement was
recognized by a telegram from President John F. Kennedy but the
project was closed down in 1966.
Since then, a
Russian-project in the far north Kola Peninsula during the 1980s has
taken over the record for the deepest borehole ever drilled, reaching 12
km into the earth's crust.
And In 2011, the oil
giant Exxon Mobil recorded an even longer borehole at just over 12 km in
eastern Russia. However, it wasn't drilled vertically downwards and
only reached soft sedimentary rocks.
"I was giving a lecture to a group of 15-year-old high-school
students recently and they [and their teachers] were fascinated by the
technology ...
Damon Teagle, University of Southampton, UK
Damon Teagle, University of Southampton, UK
While neither of these
record-drilling projects got close to the Earth's mantle, they did give
the geologists leading the new project -- The Integrated Ocean Drilling
Program (IODP) -- confidence that recent advances in drilling
techniques have made their plans more feasible than ever before.
"Many of the
technologies required are conventional deep-drilling technologies that
are presently being used in the oil and gas industry," explain IODP
geologists.
However, given the
challenges and the likely cost of $1 billion plus, much of which still
needs to be raised, skeptics may question the necessity of the mission.
For Teagle, reaching the
Earth's mantle would provide a "legacy of fundamental scientific
knowledge" and "inspire" future generations.
"I was giving a lecture
to a group of 15-year-old high-school students recently and they [and
their teachers] were fascinated by the technology and the thought that
we could re-enter a hole just a few centimeters across with a drill
string dangled from a ship in the open ocean 4 km above."
As well as the technical
achievement of bringing back samples, the samples themselves will
clarify many of the assumptions we have about how our planet works.
Despite making up 68% of the Earth´s mass, Teagle says we only have a
"reasonable" idea of what the mantle is made of and how it works.
"[The mantle] is the
engine that drives how our planet works and why we have earthquakes and
volcanoes and continents. We have the textbook cartoons but detailed
knowledge is lacking," he says.
The Japanese government
has already invested substantially in the project through the
construction of Chikyu, with some scientists regarding the mission as
the country's "moon project."
If Japanese support can
be combined with other funding, Teagle says they could start drilling
before the end of the decade, making it possible for humans to finally
reach the Earth's mantle by the early 2020s.
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