Earth Sciences / 43About 70 per cent of the Earth’s surface is covered by
water. Its albedo varies according to the angle at which
sunlight reflects from it. When the Sun is low in the
sky much more light is reflected and the water looks
brighter than when the Sun is high; in the latter case
most of its light penetrates the water and is absorbed,
and the water looks dark. Early and late in the day,
when the water is calm, the occupants of open boats
can develop sunburn quite quickly, even in cool
weather. Table 2.2 compares the incident angle of
radiation with the resultant albedo for water.
Reflected radiation does not warm the surface and so
albedo has an important climatic effect, and one that can
be modified by human intervention, although the
relationship is more complex than it may seem. The
clearance of tropical rain forest to grow field crops, for
example, involves little change, but if that change is from
forest to pasture for feeding livestock, the albedo could
double. In this case, the ground would absorb less heat,
so there would be less evaporation of water and less cloud
would form. This would reduce the average cloud albedo,
however, so increasing the amount of radiation reaching
the surface and warming it again, evaporating more water
and increasing cloudiness once more, but not necessarily
to its original value.This rather intricate relationship illustrates an important
point. Climate is strongly subject to feedback effects.
In most cases, as in our example, these tend to stabilize
conditions, as negative feedback, but positive feedback
also occurs. It exaggerates effects and so has a
destabilizing effect which can be felt rapidly, as in the
onset of glaciation and glacial melting. Eventually,
positive feedback is overridden by negative feedback
and a destabilized system finds a new level of stability.Clean air reflects no light, but air is seldom clean. It
contains very small particles, called ‘aerosols’. In the
upper troposphere and at lower levels over the open sea,
concentrations range from about 100 to 600 per cm^3 , but
at low level over continents they are much higher and in
industrial regions can reach millions. They vary in size
from 10-3 to 10^2 μm and gravity has little effect on them, because they are so small. They tend to reflect
short-wave radiation, thus increasing planetary albedo, and in saturated air water vapour will condense on
aerosols smaller than about 0.5 μm, encouraging cloud formation and also increasing albedo (and removing
the aerosols in precipitation). Increasing the albedo has a cooling effect, but aerosols absorb radiation at
infra-red wavelengths, so those in the lower atmosphere also have a warming influence; for those reaching
the stratosphere, on the other hand, the cooling influence of increased albedo is dominant. To complicate
matters further, aerosols settling on to clean snow ‘dirty’ it, reducing its albedo.Table 2.1 Albedos of various surfaces
Table 2.2 Effect of the incident angle
of radiation on water’s
albedo