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Clouds: A hot topic or are we made in the shade?
But carbon dioxide and water vapor are not the whole story. As we all
know from days at the beach, clouds block much of the solar energy and
reflect
it back to space before it can be absorbed by the Earth, the atmosphere,
or the sunbather! The more plentiful and thicker the clouds are, the
cooler the Earth. At the same time, clouds also act like greenhouse
gases-they block the emission of heat to space and inhibit the ability of
the planet to release its absorbed solar energy. To complicate matters
further, the altitude of clouds changes the amount of thermal infrared
blocking. Once again, this effect is the result of the decrease in
temperature with altitude-high clouds are colder, and are more effective
at absorbing the surface-emitted heat in the atmosphere, while they emit
very little to space because of their cold temperatures! So it turns out
that clouds can either act to cool or warm the planet depending on how
much of the Earth they cover, how thick they are, and how high they are.
The effectiveness of clouds depends on whether they are low-altitude warm
clouds made of spherical water droplets (Figure 2), or whether they are
high-altitude cold clouds made up of ice crystals with a wide range of
crystal shapes and sizes (Figure 3). In the late 1980s, the NASA Earth
Radiation Budget Experiment (ERBE) determined for the first time that on
average, clouds tend to cool the planet. The cloud reflection of sunlight
back to space dominates over the clouds' greenhouse effect. In fact, the
planet would on average be some 20°F hotter if we removed clouds from the
atmosphere. Recently, attempts have been made to combine the ERBE
satellite measurements of the radiative energy balance at the top of the
atmosphere with measurements of the radiation balance at the surface. The
objective of this combination is to infer the amount of radiation
absorbed by the intervening atmosphere. Unexpectedly, this combination
implies that the atmosphere absorbs more radiation than is theoretically
predicted. Are the observations wrong or is the theory? Do we understand
clouds?
Figure 2: Stratus clouds, which are mostly composed of liquid water droplets, reflect most of the incoming shortwave radiation (thin lines),
but re-emit large amounts of outgoing longwave radiation (thick lines).
Their overall effect is to cool the Earth.
Figure 3: Cirrus clouds, which are mostly composed of ice crystals, transmit most of the incoming shortwave radiation (thin lines), but trap
some of the outgoing longwave radiation (thick lines). Their overall
effect is to warm the Earth.
Given the large impact of clouds on the radiative energy balance, the
critical question now becomes: What effect will clouds have on surface
temperatures if global climate changes in the next century? No one knows.
Clouds could act to dampen any greenhouse gas warming by increasing cloud
cover, increasing thickness, or by decreasing in altitude. Conversely,
clouds could act to increase warming of the planet if the opposite trends
occur. In fact, the climate is so sensitive to how clouds might change,
that our current best models of global climate can vary in their global
warming predictions by more than a factor of three depending on how we
try to model the clouds.
So why can't we model clouds? The biggest problem is that clouds are
almost explosive in nature when compared to the rest of the climate
system. Cumulus clouds can form in seconds to minutes, and the entire
life cycle of a massive thunderstorm can be measured in hours. This
thunderstorm cloud may only cover 20 to 50 miles of the Earth's surface,
while our best global climate models on the world's fastest
supercomputers can only track a single column of the surface and
atmosphere every 50 to 200 miles.
back: Introduction
next: Surface Absorption and Reflection
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- Why isn't Earth as hot as an oven?
- Introduction
- Clouds: A hot topic or are we made in the shade?
- Surface Absorption and Reflection
- Atmospheric Aerosols: Fossil Fuels and Biomass Burning
- From Measurements to Climate Models
- Related Data Sets:
- Surface Temperature
- Outgoing Longwave Radiation
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