At least they have been able to
reproduce the effect in a cloud chamber and it is real. Whether it is important or not is a much
different question.
The fact remains however it is
another significant variable in any predictive climate model that could bite
us.
This does provide a clear link
between increased solar magnetic activity and increased global temperature,
noted many decades ago.
It is still a beginning and an
auspicious one.
Evidence that cosmic rays seed clouds
May 13, 2011
By firing a particle beam into a cloud chamber, physicists in Denmark and the UK
The now conventional view on global warming, as stated by the
Intergovernmental Panel on Climate Change, is that most of the warming recorded
in the past 50 years has been caused by emissions of manmade greenhouse
gases. But some scientists argue that the Sun might have a significant
influence on changes to the Earth's climate, pointing out that in centuries
past there has been a close correlation between global temperatures and solar
activity.
However, changes to the Sun's brightness are believed to have altered
temperatures on Earth by no more than a few hundredths of a degree in the last
150 years. Researchers have therefore been investigating ways that the Sun
could indirectly modify the Earth's climate, and one hypothesis, put forward
by Henrik Svensmark of the National Space Institute in Copenhagen
According to Svensmark, cosmic rays seed low-lying clouds that reflect
some of the Sun's radiation back into space, and the number of cosmic rays
reaching the Earth is dependent on the strength of the solar magnetic field.
When this magnetic field is stronger (as evidenced by larger numbers of
sunspots), more of the rays are deflected, fewer clouds are formed and so the
Earth heats up; whereas when the field is weaker, the Earth cools down.
Building clouds
The latest experiment provides evidence for a major component of
this theory – how ionization enhances cloud formation. To be converted into
droplets and form clouds, water vapour in the Earth's atmosphere needs some
kind of surface on which to condense, and this is usually provided by tiny
solid or liquid particles already present in the atmosphere, including aircraft
emissions. Svensmark's theory suggests that cosmic rays can enhance this
process by ionizing molecules in the atmosphere that then draw molecules of
water vapour to them until the aggregate is large enough to act as a condensing
surface.
To reproduce this process in the lab, Svensmark and his colleagues
filled a 0.05 m3 stainless-steel vessel with a mixture of gases
representing an idealized atmosphere – oxygen and nitrogen plus trace amounts
of water vapour, sulphur dioxide and ozone. They then shone ultraviolet light
into the vessel in order to generate the sulphuric-acid molecules around which
water molecules could aggregate, and irradiated the mixture with a beam of
580 MeV electrons supplied by the University of Aarhus
By removing samples from the vessel and counting the number of gas
clusters that measured at least 3 nm across, the researchers found that the
beam led to a significant increase in the rate at which clusters were produced.
They say that the electrons, like cosmic rays in the real atmosphere, are
ionizing molecules in the air and so cause water molecules to stick together.
Furthermore, the researchers found that this effect also took place when they
used a radioactive sodium source, which produces gamma rays, and as such claim
that similar measurements in the future will not require expensive
accelerators.
Team member Jens Olaf Pepke Pedersen of the National Space Institute at
the Danish Technical University explains that to prove the link between cosmic
rays and cloud formation, the experiment will need to be carried out for longer
in a bigger vessel. This would determine whether the clusters grow to about
100 nm, at which point they would be large enough to act as
cloud-condensing nuclei. He says that the chamber being used in the CLOUD
experiment at CERN, which has a volume of some 26 m3, might be large
enough.
Clouded science
According to Pedersen, if it can be shown that the clusters reach
the scale of micrometres, Svensmark's hypothesis will have been proven. Then,
he explains, it would be a question of finding out the significance of the
effect. "There is so much that is not known about cloud formation, so
it is possible that it could be an important component of global warming,"
he says.
However, there are problems with the cosmic-ray hypothesis. One is that
although there was a clear correlation between global temperatures and the
intensity of cosmic rays reaching the Earth's surface (as measured by neutron
counters) prior to 1970, that correlation has broken down over the last
40 years. Another problem is that a claimed correlation between cosmic
rays and global low cloud cover – as revealed in satellite observations – that
was put forward by Svensmark to support his theory has been questioned by a
number of researchers, who have found that the correlation only holds over
specific regions of time and space.
Indeed, Chris Folland, a climate researcher at the UK
The research has been published in Geophysical Research Letters.
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