Chapter 8
Gradient wind
in curved flow, there is a centripental acceleration directed inward towards the center of rotation and an apparent force called the centrifugal force directed outward
sea breeze during the day
uneven heating of the coastline during the day In areas of high P, higher P over land than over sea due to thermal expansion on shore, higher P over sea, horizontal movement of air Temperature contrast leads to P gradient force net force
Balance of forces and geostrophic wind
wherever the spacing of the isobars or height contours is wide, reduce the wind speed and strength of PGF; wherever it is narrow (isobars are close to each other), increase the wind speed, stronger PGF
subgeostrophic
Around a low (troph), the centrifugal force pulls the air in the same direction as the COR, and it is the sum of both forces that balance the PGF. Wind speed and COR are weaker. COR is proportional to wind speed. Slower than geostrophic wind.
supergeostrophic
Conditions around high pressure areas (ridge); the centrifugal force points in the same direction as the PGF. Air under goes rapid acceleration and the Coriolis force dominates the pressure gradient force. Faster than geostrophic wind.
wind speed and latitude
Influence the magnitude of the Coriolis force
Geostrophic flow
PGF balanced by Cor force
at high altitudes
The geostrophic wind concept is most like the real atmospheric winds
P gradient force
The initial force that generates wind
Upper air winds
are generally faster than surface winds
geostrophic wind
flows along lines of P, parallel to the h of the P contours, a balance b/w PGF and Cor, no acceleration
Land Breeze at night
higher P over land off shore, lower P over sea on shore, cooling of air, clouds over sea
The Coriolis effect occurs because of this characteristic of the earth
its rotation
steep pressure gradient
produces strong winds
When geostrophic conditions exist in the atmosphere...
the net force on the moving air is zero
