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by Trinity College Dublin
February
10, 2020
from
PHYS Website
Geologists studying the Lower Jurassic (Pliensbachian)
Belemnite Marl Member mudstone succession in Dorset, UK,
showing
orbitally paced variations of the sediment composition
similar
to the studied core in Wales.
Credit:
Dr Micha Ruhl
The world is waking up to the fact that human-driven carbon
emissions are responsible for warming our climate, driving
unprecedented changes to ecosystems, and placing us on course for
the sixth mass extinction event in Earth's history.
However, new research (Orbital
pacing and Secular Evolution of the Early Jurassic Carbon Cycle)
publishing this week in leading international journal PNAS,
sheds fresh light on the complicated interplay of factors affecting
global climate and the carbon cycle - and on what transpired
millions of years ago to spark two of the most devastating
extinction events in Earth's history.
Using chemical data from ancient mudstone deposits in Wales, an
international team involving scientists from Trinity College
Dublin discovered that periodic changes in the shape of
Earth's orbit around the Sun were partly responsible for changes
in the carbon-cycle and global climate during and in between,
-
the
Triassic-Jurassic Mass Extinction (around 201 million years
ago, when around 80% of the species on Earth disappeared
forever)
-
the Toarcian
Oceanic Anoxic Event (around 183 million years ago)
In addition, volcanic
activity released large amounts of greenhouse gases into the oceans
and atmosphere at that point in time, which resulted in major
global carbon cycle perturbations as well as
global climate and environmental change.
Dr. Micha Ruhl, Assistant Professor in Sedimentology at
Trinity, said:
"Our work shows that
for the 18 million years or so in between the Triassic-Jurassic
mass extinction and the Toarcian Oceanic Anoxic Event,
Earth's global carbon-cycle was in a constant state of
change."
Eccentricity of the Earth's orbit around the Sun.
The fluctuation between a nearly circular and elliptical orbit
drives cyclic changes in the Earth's environment,
including the global carbon cycle.
Credit: Marisa Storm
"Periodic changes in
the shape of Earth's orbit around the sun impacted on the amount
of energy received by Earth from the sun, which in turn impacted
climatic and environmental processes, as well as the
carbon-cycle, on local, regional and global scales."
"Although this phenomenon is well known for having caused the
glacial cycles in more recent times, the present study shows
that these external forcing mechanisms on Earth's systems were
also operating, and controlling Earth's carbon cycle in the
distant past, even during non-glacial times when Earth was
marked by hot-house climate conditions."
Present-day orbital
configurations and solar system processes should have resulted in a
future return to glacial conditions.
However, anthropogenic
carbon release will likely have disrupted this natural process,
causing rapid
global warming, rather than a
steady return to cooler climates.
The study of past global change events, such as the
end-Triassic mass extinction
and the
Toarcian Oceanic Anoxic Event,
as well as the time in between, allows scientists to disentangle the
different processes that control global carbon cycle change and
constrain tipping points in Earth's climate system.
A major international research team, made up of scientists from
across Europe, North and South America and China, and including Dr.
Micha Ruhl and other researchers from Trinity, will soon
commence drilling a 1 km deep borehole to retrieve rock samples.
These samples will comprise detailed climatic and environmental
information and allow for further improved understanding of the
processes that led to past major global change events and mass
extinctions.
Drilling of this borehole
will occur as part of the International Continental Scientific
Drilling Program (ICDP).
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