Transcript Slide 1

Lecture 7
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Forces (gravity, pressure gradient force)
Imaginary forces (Coriolis, centrifugal)
Force balance and resulting horiz. wind
Geostrophic wind
Gradient wind
Adjustment to balance
The thermal “wind” (change in geostrophic
wind in the vertical)
Wind direction is the direction from which the
wind is blowing. Wind direction is expressed in
degrees
Units: m/s or knots
1 knot = 0.5 m/s
1knot ~ 1 mile/hr
Wind speed is
expressed in terms
of the flagpole
Newton’s law of motion
• A body at rest tends to stay at rest; a body
in motion tends to stay in motion, traveling
at a constant speed in a straight line.
• A force exerted on a body of mass m
causes the body to accelerate in the
direction of the applied force.
Force = mass x acceleration
A force has direction and magnitude (it is a
vector). Adding two forces is vector addition.
Forces that move the air
• Gravitational force (g=9.8 m/s2)
• Pressure gradient force (-1/rho x dp/dx or -1/rho x dp/dy). It points toward lower p.
The pressure gradients causing the wind
are horizontal.
• Coriolis force
• Centrifugal force
• Frictional force
Pressure gradient force pushes from
higher to lower pressures
PGF
Magnitude depends on value of pressure gradient
Isobaric chart (height contours on a
constant pressure surface)
Pressure (p) as a function of height
Vertical structure in the atmosphere
• What about pressure?
• Hydrostatic equation: balance between pressure
gradient force and gravity.
– dp/dz = - rho g
• Ideal gas law:
– p = rho R T
Let’s go to the board!
z = - H ln (p/p0), where H is scale height and is only constant
if T is constant.
In other words, p = p0 exp(- z/H)
Next: Coriolis force
Earth’s rotational speed is greatest at the
equator and exactly zero at the poles
Coriolis deflection
Coriolis force deflects
moving air to the right
in the Northern Hemisp.
Coriolis force deflects
moving air to the left
in the S. Hemisphere
The magnitude of the Coriolis force (CF) is
proportional to the wind speed and sine of latitude
CF= f x V,
Where f is
2xEarth’s
rotation rate
xsin(latitude)
Centrifugal force: arises because the
trajectory is curved. CENTF= V^2/R, where R
(radius of curvature) is positive for cyclones,
negative for anticyclones
Frictional force is proportional to the windspeed and directed opposite to the wind dir.
FF = -k V (where k describes the roughness)
Summary: The Forces
• Gravity – the strong silent type
• PGF arises from pressure gradients
generated by differential solar heating –
leads to wind. Only then do the other
forces start acting.
• CF, CENTF, FF all depend of V, wind
speed.
Atmospheric force balances
Sum of forces = mass x acceleration
Balance when the forces add up to zero
• Hydrostatic balance in the vertical (gravity
does not cause wind).
• Strong horizontal PGF means strong wind
• CF changes wind direction not speed
• CENTF only acts on curved flow
• FF slows down the wind (regardless of
direction).
Geostrophic wind, geostrophic balance
PGF + CF = 0
Wind blows counterclockwise around lows
(cyclonic wind in cyclones), clockwise
around highs (anticyclones)
Force balance not quite right since we have curved flows
Add centrifugal force
Gradient balance and the gradient wind
Gradient balance results in gradient wind
• Represents balance of three forces
• It is an excellent approximation to free
atmospheric flow.
• Around highs it is supergeostrophic
• Around lows it is subgeostrophic
Adjustment to balance
• The atmosphere tries hard to stay in
balance, but it is constantly being pushed
away from it.
• The atmosphere adjusts very quickly (in a
matter of minutes) to imbalance.
Adjustment to balance with 3 forces: