CLAYTON SOUTH, Victoria -- A clear change in salinity has been detected in the world's oceans, signaling shifts and an acceleration in the global rainfall and evaporation cycle.
In a paper published today in the journal
Science, Australian scientists from CSIRO and the Lawrence Livermore
National Laboratory, California, reported changing patterns of salinity
in the global ocean during the past 50 years, marking a clear
fingerprint of climate change.
Lead author, Dr Paul
Durack, said that by looking at observed ocean salinity changes and the
relationship between salinity, rainfall and evaporation in climate models,
they determined the water cycle has strengthened by four percent from
1950-2000. This is twice the response projected by current generation global climate models.
"Salinity shifts in the ocean confirm climate and the global water cycle have changed.
"These changes suggest that arid regions have
become drier and high rainfall regions have become wetter in response to
observed global warming," said Dr Durack, a post-doctoral fellow at the
Lawrence Livermore National Laboratory.
With a projected temperature rise of 3ÂșC by the
end of the century, the researchers estimate a 24 per cent acceleration
of the water cycle is possible.
Scientists have struggled to determine coherent
estimates of water cycle changes from land-based data because surface
observations of rainfall and evaporation are sparse. However, according
to the team, global oceans provide a much clearer picture.
"The ocean matters to climate – it stores 97 per
cent of the world's water; receives 80 per cent of the all surface
rainfall and; it has absorbed 90 per cent of the Earth's energy increase
associated with past atmospheric warming," said co-author, Dr Richard
Matear of CSIRO's Wealth from Oceans Flagship.
"Warming of the Earth's surface and lower
atmosphere is expected to strengthen the water cycle largely driven by
the ability of warmer air to hold and redistribute more moisture."
He said the intensification is an enhancement in
the patterns of exchange between evaporation and rainfall and with
oceans accounting for 71 per cent of the global surface area the change
is clearly represented in ocean surface salinity patterns.
In the study, the scientists combined 50-year
observed global surface salinity changes with changes from global
climate models and found "robust evidence of an intensified global water
cycle at a rate of about eight percent per degree of surface warming."
Dr Durack said the patterns are not uniform,
with regional variations agreeing with the 'rich get richer' mechanism,
where wet regions get wetter and dry regions drier.
He said a change in freshwater availability in
response to climate change poses a more significant risk to human
societies and ecosystems than warming alone.
"Changes to the global water cycle and the
corresponding redistribution of rainfall will affect food availability,
stability, access and utilization," Dr Durack said.
Dr Susan Wijffels, co-Chair of the global Argo
project and a co-author on the study, said maintenance of the present
fleet of around 3,500 profilers is critical to observing continuing
changes to salinity in the upper oceans.
The work was funded through the Australian Climate Change Science Program,
a joint initiative of the Department of Climate Change and Energy
Efficiency, the Bureau of Meteorology and CSIRO. Dr Durack is a graduate
of the CSIRO-University of Tasmania Quantitative Marine Science
program and he received additional support from CSIRO's Wealth from
Oceans Flagship. Work undertaken at Lawrence Livermore National
Laboratory is supported by the U.S. Department of Energy under contract
DE-AC52-07NA27344.
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