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Lecture 2

# EESA09H3 Lecture Notes - Lecture 2: Coriolis Force, Fictitious Force, Northern Hemisphere

Department
Environmental Science
Course Code
EESA09H3
Professor
Tanzina Mohsin
Lecture
2

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EESA09H WIND
Lecture 2 Notes
1. Outline of this lecture
a. Part 1: Wind Primer
b. Part 2: New air mass classification system â€“ applied to Toronto
2. Part 1. Wind Primer
What is wind?
Wind cannot be seen directly but can be inferred by its effects such as the movement
of objects (trees, grass) and causing objects to become airborne (dust). Wind can be felt
and it can be heard.
Wind results from the differences in air pressure, either vertical or horizontal.
Differences in pressure produce a pressure gradient. In the absence of other forces air
tends to move from high pressure to low pressure. The force that causes this is called the
Because the earth rotates, another force does act on the wind. It is called a
fictitious force because it directly results from this rotation of the earth. It is called the
Coriolis force. In the Northern Hemisphere it acts to deflect the wind to the right and in
the Southern Hemisphere it acts to deflect the wind to the left. A French nobleman,
Gustave de Coriolis derived the mathematical formulation in 1835, although Englishman
Above the surface of the earth (1 km or more) there is a balance between pressure
gradient force and the Coriolis force forming the geostrophic wind. The only way to
achieve a balance between these forces is for the wind to flow perpendicular to the

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pressure gradient. This is a wind that is not directed toward a low pressure or from a high
pressure, counter to intuition.
At and near the surface, friction plays a role forming a three way balance of
forces. In this instance there is a component of the wind that flows towards the centre of a
low and away from the high pressure centre. This surface convergence of winds at the
centre of a low is critical for the formation of midlatitude cyclones as will be detailed in
Lecture 4.
3. Global circulation
Although the upper atmosphere (in particular the stratosphere) experiences winds, we
will focus on the winds in the troposphere. The basic physics behind the formation of
winds is pressure differences. As described above, air has a natural inclination to move
from areas of high pressure to those of low pressure. This is modified by several factors.
Earthâ€™sî€ƒrotationî€ƒcreates the Coriolis effect, which causes the wind to deflect (to the right
in the northern hemisphere and to the left in the southern hemisphere). Earthâ€™sî€ƒsurfaceî€ƒ
contributes friction which slows down and redirects (funnels) the wind. Land/sea contrast
leading to temperature differences between land and water surface also influences wind.
Finally, winds vary with season.
On the global scale there are three main circulation cells per hemisphere. These are
These consist of vertical and horizontal winds. The Hadley cell is characterized by air
rising in the equatorial region, driven by warm surface conditions. In the upper
troposphere this air starts to move horizontally towards the poles. At 30ï‚°N and 30ï‚°S, air
descends to the surface. At the surface the air returns to the equatorial region to complete
the circulation. This circulation occurs in both the northern and southern hemispheres.
Poleward of the Hadley cell is the Ferrel cell. This cell shares the descending branch of
air at 30ï‚°N and S with the Hadley cell. At the surface, the air moves poleward until about
60ï‚°N and S and then ascends. The circulation is completed by a return flow equatorward
in the upper troposphere. The Polar cell shares the ascending branch with the Ferrel cell
at 60ï‚°N and S. In the upper troposphere the air from this cell flows poleward and then

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descends at the pole. To complete circulation, air flows equatorward at the surface to
60ï‚°N and S.
If the world did not rotate, this simple picture would be a good model for the winds at
the surface of the earth. However, the earth does rotate and this causes a deflection of
winds due to the Coriolis force (take EESB03H3, Principles of Climatology to find out
more about the Coriolis Effect). As a result we have a surface distribution of winds that
are different than this three cell model would initially suggest. Between the equator and
30ï‚°N the wind should flow to the south. However, with the rotational deflection the
winds actually flow to the southwest; these are called the Trade Winds. They are the
steadiest winds in the world. They were used in the 15th and 16th century by Europeans to
explore North America (Christopher Columbus used them in 1492).
In the absence of rotation the winds from 30ï‚° to 60ï‚°N should flow north. The
rotational deflection causes these winds to move in a northeast direction. These are called
the Westerlies, named for the direction from which they come (not the direction they are
heading). The Westerlies are the prevailing wind in the midlatitudes and therefore the
predominant wind in Toronto. North of the Westerlies we should get winds flowing south
from the pole to 60ï‚°N. However with the deflection these winds head to the southwest
and are called polar easterlies indicating the direction from which they come from.
The horse latitudes occur near 30ï‚°N and 30ï‚°S. This is a region of little wind between
Westerlies and Trade Winds and corresponds to the descending branch of Hadley/Ferrel
cells. It was named by European sailors; ships in this region did not make much progress
because there is no strong prevailing wind. Thus, they had to jettison some of their cargo
â€“ which included horses (the livestock would die off as water and food ran out). The
doldrums are a region of little wind between North and South Trade Winds. This
corresponds to the ascending branch of two Hadley cells, also called the Intertropical
Convergence Zone (ITCZ) because of the surface convergence of air from either side of
the equator. The Polar Front is a very active region between the Ferrel and Polar cells,
where cold air and warm air collide. It is the source of the most intense large scale storms
in the midlatitudes (more on this in Lecture 4). It meanders north and south considerably
with season.