Lab week 10_Nhu Vo
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School
California State University, Chico *
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Course
110
Subject
Geography
Date
Jan 9, 2024
Type
docx
Pages
9
Uploaded by ProfDonkey2390 on coursehero.com
Lab 8: Atmospheric and ocean
circulation
(C
HANGED
FROM
P
ROF
. K
AREN
G
ROVE
, S
AN
F
RANCISCO
S
TATE
U
NIVERSITY
)
Objective
The objective of this lab is to view data that illustrate how the ocean circulates. Oceanic
circulation greatly influences climate, which affects us all. The atmosphere and ocean work
together to absorb heat and redistribute it from one part of the globe to another. Otherwise, the
tropics would get hotter and hotter, and the polar regions would get colder and colder. The ocean
circulates by surface currents that are driven mainly by the wind, and by deep currents that are
driven mainly by density contrasts in the water produced by temperature and salinity variations.
Because the wind drives surface currents, we must also look at how the atmosphere circulates. In
this lab we will primarily investigate evidence of surface currents. Because of the large scale of
oceanic currents, observations from satellites are often used to study their characteristics and
variations.
Background Ekman transport and currents
Before you start you should remember and be able to predict in which directions the surface
currents are flowing. In order to do this, you need information about the atmosphere and the
water:
Figure 1: Illustration of processes at high- and low-pressure regions
In warm areas, air rises from the surface and leads to a low-pressure zone. In colder areas,
sinking air is associated with a high-pressure zone (Figure 1).
Hence at the surface there is a pressure gradient from high to low pressure. This pressure
gradient leads to the movement of air from high- to low-pressure regions.
However, the Coriolis force leads to a reflection of the moving air to the right on the northern
hemisphere and to the left on the southern hemisphere.
Furthermore, Oceans have a greater heat capacity than land because the specific heat of water is
greater than that of dry soil and because mixing of the upper ocean results in a much larger mass
1
of water being heated than land. This causes land areas to heat more rapidly and to higher
temperatures and also to cool more rapidly and to lower temperatures, compared to oceans.
Hence, the difference in the heat capacity leads to a switch of high and low pressure zones
between day and night and between seasons.
Now, wind moves water, but the overall water transport is not in the direction of the wind.
Friction between each layer of water molecules leads to an overall water transport that is 90
o
the
right on the northern hemisphere and to the left on the southern hemisphere. This change in
direction is again a result of the Coriolis force. This water transport is called Ekman transport
(Figure 2):
Figure 2: Ekman transport model.
Ekman transport pushes water away, which leads to a change in sea level. The sea level is higher
in the direction of the water transport, and lower in the region where the water was pushed from
(Figure 3).
2
Figure 3: Ekman transport and changes in sea level.
This means that the weight of the water column will be higher on the "piled up" side of the
basin, and gravity will act to pull the water back down the slope in the direction it came. But
remember, rather than simply moving back and forth in response to the force of wind versus
gravity, the Coriolis effect causes the flow to be deflected either to the right (in the Northern
Hemisphere) or to the left (in the Southern Hemisphere). This deflection of water leads to
geostrophic surface currents
Part I. Determine Ekman transport and geostrophic
currents on an Earth without land.
You can use your own colors
or type of arrows, but then
provide a legend or follow
instruction below
1.
The black arrows
present the general
wind directions in the
different latitudes.
2.
Draw with a red
pencil the direction of
the Ekman transport
for the different wind
directions. (6 points)
3.
Determine the areas
of convergence
(C)and divergence
(D). Areas of
convergence is where
water would pile up,
and a region of
divergence is where
water would be
pushed away. Label
with a black pencil (5
points)
If you cannot draw this directly on the word document, draw the required image on a piece of paper,
take a picture and copy and paste here.
3
Part II: Identify wind, Ekman transport and currents if land
is present and during different seasons.
So now you have determined the direction of the general surface currents, the wind, and the Ekman
transport if there is no land present. But what happens when land is present? Again, you can choose
your own color or even symbols. The colors I mentioned are just suggestions.
a.
Consider Peru. In general, there is a barometric high on the Ocean and barometric low on land.
Please draw the direction of the wind (black), Ekman transport (red) and geostrophic current
(green) next to the image. (3 points)
Write H and L for high- and low-pressure zones.
Use a dashed line to indicate in which direction wind tries to blow (wind because of the
pressure gradient)
Peru is on the Southern hemisphere; hence wind is 90
o
deflected to the left from the
pressure gradient.
Now draw the Ekman transport which is 90
o
to the left of the wind direction.
In rough approximation, are 45
o
to the left of the wind direction.
Determine if upwelling or downwelling is occurring
off the coast of Peru.
4
Land
Ocean
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