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Fronts
Frontal Depressions
Other types of depression (or low)
Anticyclones
A front is the boundary between two different types
of air
mass. In our latitudes a front usually separates
warm, moist air from the tropics and cold, relatively
dry air from polar regions.
Fronts move with the wind, so in the UK this is normally
from west to east because our prevailing winds are
from the west or southwest. At a front, the heavier
cold air undercuts the less dense warm air, causing
the warm air to rise up over the wedge of cold air.
As the air rises there is cooling and condensation,
thus leading to the formation of clouds and rainfall.
Consequently, fronts tend to be associated with cloud
and rain. Three types of front can be identified;
warm fronts, cold fronts and occluded fronts.
Warm
front
A warm front marks the leading edge of a warm air
mass. The presence of a warm front means that the
warm air is advancing and rising up over the cold
air. This is because the warm air is 'lighter' or
less dense, than the colder air. Warm air is thus
replacing cold air at the surface.
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| Fig 1: A warm front in diagrammatic form |
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| Fig 2: Cross-section through a warm front,
with associated cloud, temperature and weather
changes |
Cloud extends well ahead of the front, becoming thicker
as the front approaches, accompanied by falling pressure.
Rain then starts to fall, usually becoming heaviest
on the front itself.
The passage of the front is followed by a rise in
temperature and humidity and a veer in the wind, while
the pressure also stops falling. Although the rain
dies out, it often stays cloudy.
On windward coasts and hills, the cloud base may
be low enough to give fog and thick enough to produce
drizzle. Inland and to the lee of hills, the cloud
may break, allowing for some warm sunshine.
Cold
front
This marks the leading edge of colder air. The presence
of a cold front means that cold air is advancing and
pushing underneath warmer air. This is because the
cold air is 'heavier' or denser, than the warmer air.
Cold air is therefore replacing warmer air at the
surface.
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| Fig 3: A cold front in diagrammatic form |
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| Fig 4: Cross-section through a cold front,
with associated cloud, temperature and weather
changes |
Pressure begins to fall increasingly rapidly as the
front approaches and rain usually starts not long
before it arrives, becoming heavy for a short time.
This is often accompanied by an increase in and a
backing of the wind. In some cases, there may also
be hail and thunder.
The passage of the front is usually marked by a sharp
change from falling to rising pressure and a veer
in the wind.
As the rain dies away, the cloud lifts and breaks
and, although there is sunshine, the air temperature
falls.
After a time, cumulus clouds begin to form, often
bringing showers. Sometimes the showers may become
heavy, perhaps even accompanied by hail and thunder.
On the other hand, in some cases, pressure will rise
rapidly after a cold front has passed and this causes
there to be few, if any, showers.
Occluded
front or occlusion
Occlusions are slightly more complex than warm or
cold fronts. They occur because cold fronts travel
more quickly than warm fronts and eventually this
results in the cold front 'catching up' with the warm
front.
This causes the warm air to be undercut and lifted
up from the surface.
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Fig 5: An occluded front in diagrammatic
form
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The characteristics of an occlusion are similar
to those of a cold front in that the rain belt
is narrow.
Cloud lifts and breaks after the front has
moved through and there may be a change in temperature
and a veer in the wind, though these tend to
be small.
Fig 6: The point of
occlusion
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Trough
Whereas fronts separate air masses, which are different
in temperature, troughs generally develop in cold
air and are characterised by an increase in the frequency
and intensity of showers. Pressure begins to fall
as the trough approaches and often rises sharply once
it has passed. As with fronts, the wind tends to back
ahead of the trough and to veer immediately behind
it. There are also particularly strong gusts of wind
in the showers
Summary
- Fronts form as the result of 'conflict' between
warm and cold air
- Fronts are the boundary between two air masses
- The most significant weather occurs on fronts,
since that is where the air is rising fastest
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Introduction
Development of a depression
Weather associated with a classic
depression
Introduction
A depression is an area of low pressure and is associated
with unsettled weather. This is due to the fact that
the air within the depression is rising, causing it
to cool and the water vapour within it to condense
into clouds. This rising air within a depression causes
an area of low pressure at the surface. The deeper
the depression (or low), the more unsettled the weather.
Consequently, the weather associated with a depression
is often cloudy, wet and windy. However, weather is
not uniformly distributed around a depression. Different
parts of it have very different types of weather,
which also vary through its lifetime. The most significant
weather (cloud and precipitation) occurs in discrete
lines or fronts. In the northern hemisphere winds
blow anticlockwise around areas of low pressure; this
is reversed in the southern hemisphere.
Development
of a depression
Stage 1 - Origin and infancy
The depression usually starts life as a wave, shown
on a chart by 'buckling' on a front. At this stage,
the air is warm to the south of the front and relatively
cold to the north of it. The weather in the warm air
can vary from fine and sunny to cloudy, sometimes
with drizzle and perhaps even with fog. The type of
cloud is layered or stratiform
and is not very thick. In the cold air, there is usually
some cloud, but it tends to be more broken, appearing
as discrete speckles on a satellite image. The cloud
is cumuliform
and can often be large enough to produce showers.
Figure 7 shows an example of a 'wave' on a
synoptic chart, whilst Figure 8 shows the infrared
satellite image for the same time.
- In warm air, the weather can vary from warm and
sunny to dull and drizzly
- Colder air is more showery, but with some sunshine
too.
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| Fig 7: Synoptic chart, 7
Sep 2005, 1200 GMT |
Fig 8: Infrared satellite
image, 7 Sep 2005, 1200 GMT |
Stage 2 - Maturity
As the depression develops, the pressure around it
falls, leading to more tightly packed isobars. This
causes winds to be stronger and, at the same time,
the buckle in the front becomes much more marked (see
Figure 9), with distinct warm and cold
fronts being formed. Warm air is pushed towards
the north while colder air drives southwards. The
region between the warm and cold front is called the
warm sector. The cloud near the fronts thickens
and the frontal zone becomes broader, which
means that rain is more prolonged, becoming heavier
nearer the front. However, it is often the case that
one front is more active than the other. At this stage,
the heaviest rain occurs near the centre of the low.
Figure 9 shows an example of a mature 'depression'
on a synoptic chart, whilst Figure 10 shows
the infrared satellite image for the same time.
- The weather on or near a front is usually cloudy,
with precipitation that may vary from virtually
nothing on a weak front to a torrential downpour
on a particularly active one
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| Fig 9: Synoptic chart, 8 Sep 2005, 1200 GMT
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Fig 10: Infrared satellite image, 8
Sep 2005, 1200 GMT |
Stage 3 - Occlusion
The fronts move at a speed indicated by the separation
between the isobars along them, although the speed
of the warm front is about two-thirds of this. Consequently,
the cold front is usually faster than the warm front.
Cold air is denser than warm air, which it replaces
at the surface, causing the warm air to lift and the
warm sector to become progressively smaller. The cold
air increasingly undercuts the warm air, initially
from near the centre of the low, leading to the development
of an occluded front, or occlusion (see Figure
11).
The rainfall usually becomes more sporadic on an
occlusion, with the heaviest rain occurring near the
triple point (see Figure 11), where
all three types of front meet. By this stage, a depression
is now in its mature stage, the pressure of its centre
stops falling and starts to rise. Cold air has been
brought well to the south, often over areas with higher
surface temperatures. This can lead to particularly
heavy showers, some of which may be thundery. Showers
sometimes become organised into lines, which can be
indicated on the weather chart by troughs (see
Figure 11). Figure 11 shows an example
of an occluded depression on a synoptic chart, whilst
Figure 12 shows the infrared satellite image
for the corresponding time.
- Troughs are organised lines of precipitation,
which can often be quite heavy
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| Fig 11: Synoptic chart, 9 Sep 2005, 1200 GMT |
Fig 12: Infrared satellite image, 9
Sep 2005, 1200 GMT |
Stage 4 - Death
Eventually the frontal system dies as all the warm
air has been pushed up from the surface and all that
remains is cold air. The occlusion dies out as temperatures
are similar on both sides of the front.
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| Fig 13: Animation of the life cycle of
a depression, 7 Sep 2005, 0000 GMT to 9 Sep 2005,
1800 GMT |
Weather
associated with a classic depression
Every depression is different and hence the weather
associated with each depression is also unique. However
the weather associated with the passage of a classic
depression does follow some general trends. Table
1 details the changes associated with the passage
of both warm and cold fronts, whilst Figure 14
shows a cross section through a mature depression.
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| Figure 14: Cross-section through a classic
depression |
Table 1: Weather
associated with the passage of a classic depression
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Ahead of the warm
front |
Passage of
the warm front |
Warm sector |
Passage of
the cold front |
Cold sector |
| Pressure |
starts to fall steadily |
continues to fall |
steadies |
starts to rise |
continues to rise |
| Temperature |
quite cold, starts
to rise |
continues to rise |
quite mild |
sudden drop |
remains cold |
| Cloud cover |
cloud base drops and
thickens (cirrus and altostratus) |
cloud base is low and
thick (nimbostratus) |
cloud may thin and
break |
clouds thicken (sometimes
with large cumulonimbus) |
clouds thin with some
cumulus |
| Wind speed
and direction |
speeds increase and
direction backs |
veers and becomes
blustery with strong gusts |
remain steady, backs
slightly |
speeds increase,
sometimes to gale force, sharp veer |
winds are squally |
| Precipitation |
none at first, rain
closer to front, sometimes snow on leading
edge |
continues, and sometimes
heavy rainfall |
rain turns to drizzle
or stops |
heavy rain, sometimes
with hail, thunder or sleet |
showers |
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Back to top
| Other types
of depression (or low) |
Polar lows
Thundery lows
Lee lows
Polar
lows
Polar lows form in cold air, mainly in winter or
spring, and tend to be quite small. They usually originate
from eddies that form to the lee of high ground. They
produce showers that are wintry in nature and which
sometimes become aligned into troughs. When they come
across land, they can produce quite large amounts
of snowfall. Figure 15 shows an example of
a polar low on a synoptic chart, whilst Figure
16 shows the infrared satellite image for the
corresponding time.
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| Fig 15: Synoptic chart, 25 Dec 2004, 0000 GMT
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Fig 16: Infrared satellite image, 25
Dec 2004, 0000 GMT |
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Thundery
lows
Thundery lows form over hot land in summer
and can produce a large number of thunderstorms.
These thunderstorms can also become aligned
into troughs, giving spells of particularly
intense downpours with hail, occasionally accompanied
by tornadoes or waterspouts.
Figure 17 shows an example of thundery
lows over France and Spain on a synoptic chart.
Figures 18 and 19 show satellite
images for the same day, showing the development
of thunderstorms during the day.
Fig 17: Synoptic chart,
14 Jul 2003, 1800 GMT
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| Fig 18: Infrared satellite image, 14
Jul 2003, 1400 GMT |
Fig 19: Infrared satellite image, 14
Jul 2003, 2200 GMT |
Lee lows
Lee lows form to the lee of high ground when strong
winds are blowing directly against a ridge. They don't
produce any particular type of weather, but winds
around them can be very unpredictable in both speed
and direction. Figures 20 and 21 show
an example of a lee low over the Gulf of Genoa on
both a synoptic chart and satellite image.
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| Fig 20: Synoptic chart, 7 Oct 2003, 1200 GMT |
Fig 21: Infrared satellite image, 7
Oct 2003, 1200 GMT |
Back to top
An anticyclone is a region of high pressure. This
is the result of the air in the atmosphere subsiding
towards the earth's surface. This subsidence, or sinking
motion, leads to the air becoming drier and warmer.
In the northern hemisphere winds blow clockwise around
areas of high pressure, this is reversed in the southern
hemisphere.
When anticyclones form over land, the skies above
are often clear of cloud. During the summer, this
means long, sunny days and clear nights. In winter,
the longer nights mean that temperatures fall lower,
with frost often forming, which may persist all day.
The falls in temperature overnight and light winds
can lead to fog forming.
When anticyclones are over the sea, the weather can
vary from fine and sunny to overcast cloud. This cloud
may be thick enough to give drizzle and may fall low
enough to produce fog. This happens most often during
spring and is least frequent in autumn. If the anticyclone
extends over both land and sea, cloud and fog can
spread across coastal regions, sometimes reaching
quite far inland.
- In summer over land, days are warm or hot and
sunny, nights are clear.
- Over the sea, it is sometimes quite cloudy. Drizzle,
mist or fog are most likely early in the summer.
- In winter over land, days are often dull and misty,
perhaps even foggy. Sunny days tend also to be cold
and dry. Nights can be clear and frosty, or become
foggy or cloudy.
- Over the sea, the winter weather is much the same
as during the summer. Drizzle, mist or fog become
more likely as spring approaches.
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| Fig 22: Synoptic chart, 11 Apr 2005, 1200 GMT
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Fig 23: Visible satellite image, 11 Apr
2005, 1200 GMT |
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