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Tree roots in
the mountains 'acted like a thermostat' for millions of years
Date:
February 5,
2014
Source:
University of Oxford
Summary:
For the first time, scientists have
discovered how tree roots in the mountains may play an important role in
controlling long-term global temperatures. Researchers have found that
temperatures affect the thickness of the leaf litter and organic soil layers,
as well as the rate at which the tree roots grow. In a warmer world, this means
that tree roots are more likely to grow into the mineral layer of the soil,
breaking down rock into component parts which will eventually combine with
carbon dioxide. This process, called weathering, draws carbon dioxide out of
the atmosphere and cools the planet. The theory suggests that mountainous
ecosystems have acted like Earth's thermostat, addressing the risk of
'catastrophic' overheating or cooling over millions of years.
For the
first time, scientists have discovered how tree roots in the mountains may play
an important role in controlling long-term global temperatures.
Researchers
from Oxford and Sheffield Universities have found that temperatures affect the
thickness of the leaf litter and organic soil layers, as well as the rate at
which the tree roots grow. In a warmer world, this means that tree roots are
more likely to grow into the mineral layer of the soil, breaking down rock into
component parts which will eventually combine with carbon dioxide. This
process, called weathering, draws carbon dioxide out of the atmosphere and cools
the planet. The researchers say this theory suggests that mountainous
ecosystems have acted like Earth's thermostat, addressing the risk of
'catastrophic' overheating or cooling over millions of years.
In their
research paper published online in Geophysical Research Letters, the
researchers carried out studies in tropical rain forests in Peru, measuring
tree roots across different sites of varying altitude -- from the warm
Amazonian Lowlands to the cooler mountain ranges of the Andes. They measured
the growth of the tree roots to 30 cm beneath the surface, every three months
over several years. At each of the sites, they also measured the thickness of
the organic layer above the soil. This information was then combined with
existing data of monthly temperature, humidity, rainfall, and soil moisture in
order to calculate the likely breakdown process of the basalt and granite rocks
found in the mountain ranges of Peru.
Using this
model, based on field data in Peru, the scientists were able to scale up in order
to calculate the likely contribution of mountain forests worldwide to global
weathering rates. The researchers then calculated the likely amount of carbon
to be pulled out of the atmosphere through weathering when Earth became very
hot. They looked at the volcanic eruptions in India 65 million years ago (known
as the Deccan traps). The model also allowed them to calculate the weathering
process and carbon feedback after Earth's cooling 45 million years ago, when
great mountain ranges like the Andes and the Himalayas were first formed. The
paper suggests that mountainous regions may play a particularly important role
in drawing carbon out of the atmosphere because they have abundant volcanic
rock which is highly reactive to weathering when it disintegrates.
Lead
researcher Chris Doughty, from the School of Geography and the Environment at
the University of Oxford, said: "This is a simple process driven by tree
root growth and the decomposition of organic material. Yet it may contribute to
Earth's long-term climate stability. It seems to act like a thermostat, drawing
more carbon dioxide out of the atmosphere when it is warm and less when it is
cooler.
"A
series of climatic events over the last 65 million years ago have resulted in
global temperatures rising and falling. However, the weathering process that
regulates carbon dioxide in the atmosphere may be buffered by forests that grow
in mountainous parts of the world. In the past, this natural process may have
prevented the planet from reaching temperatures that are catastrophic for
life."
Co-author
Yadvinder Malhi, Professor of Ecosystem Science at Oxford University, said:
"This study shows how trees can act as brakes on extreme climate change,
and the roots of trees in tropical mountains such as the Andes play a
disproportionate role. However, these responses take thousands to millions of
years and cannot do much to slow the rate of global warming we are experiencing
this century."
Story
Source:
The above
story is based on materials
provided by University of
Oxford. Note: Materials may be edited for content and length.
Journal
Reference:
- Christopher E. Doughty, Lyla L. Taylor, Cecile A. J. Girardin, Yadvinder Malhi, David J. Beerling. Montane forest root growth and soil organic layer depth may have stabilized Cenozoic global change. Geophysical Research Letters, 2014; DOI: 10.1002/2013GL058737
