Ocean Chapter Notes

advertisement
THE CAUSES OF OCEAN CIRCULATION
The Field of Oceanography:
Oceanography, the study of the oceans, is a vast scientific discipline that draws upon many aspects of
physics, chemistry, and biology.
Physical oceanography, one of many branches of oceanography, is the study of water motions in the
ocean.
Other well-developed areas in oceanography include chemical oceanography and biological
oceanography.
There are also marine geology, marine geophysics, and marine acoustics.
The Study of Waves:
The force exerted by the wind on the water surface generates waves, which then run in the direction of
the wind.
The generation of waves from an initially calm surface is itself mechanically complex.
Once initial irregularities are formed by the friction of the wind, the waves grow because the differences
in air pressure on the upwind side of the wave and the downwind side of the wave serves to make a
crest grow and the trough deepen.
Size of Waves:
The size of the water waves depends on three factors,
1) Wind Speed
2) Wind Direction
3) Fetch
Stronger winds generate larger waves.
The distance of water surface over which the wind blows is called the fetch of the wind.
Movement of Waves:
Coriolis forces do not affect waves: they move in a straight-line direction for long distances across the
ocean.
The reason is that the water does not move with the waves.
What Drives Water Movement in the Oceans?:
With the exception of the tides, which do not figure importantly in this chapter, virtually all of the largescale water motions in the oceans are caused by global temperature differences, either directly or
indirectly.
The Hotter the surface, the stronger the radiation and the shorter the wavelength of the radiation.
The circulation in the oceans consists of two largely separate parts: The deep circulation, which is driven
directly by latitudinal temperature differences, and the surface circulation, which is driven by the Earth’s
wind systems.
These wind systems are in turn driven by the latitudinal temperature differences.
The Coriolis Effect:
The Earth’s rotation introduces great complexity to the circulation of the oceans, as well as to the
Earth’s wind systems.
In accordance with Newton’s First Law of Motion, once air in the atmosphere or water in the oceans are
set in motion, they tend to move at constant speed and in a straight line, to the extent that they are not
acted upon by frictional forces.
Meanwhile, the Earth is rotating relative to that outer-space observer; moreover; it is rotating relative
to the moving water.
To an observer (i.e. to you) fixed upon the rotating Earth, the air and water seem to be moving in a
curved path; in reality, however, it is you—not the air or water—that is moving in a curved path.
The Coriolis force is not really a force: it is a consequence of viewing a moving body from a rotating
frame of reference.
Ocean Currents Affect Climate:
There is a very close connection between ocean currents and climate, both global and local.
The pattern of ocean surface currents is also a major factor in the climate of land areas of
subcontinental size.
The specific heat capacity of a material is a measure of how much heat must be added, per unit mass, to
raise the temperature of the material by one unit.
Warm ocean waters are the main suppliers of water vapor to the atmosphere.
Most of the precipitation along the eastern seaboard of the United States, in both winter and summer,
originates from the warm water of the Gulf of Mexico and western Atlantic.
Climate Affect Ocean Currents:
Climate can have a major effect on ocean circulation.
The average deep ocean depth is four or five kilometers, the bottom of the deep ocean is a place of inky
blackness, eternal cold, and water pressures that are unimaginably large, however even the deep
oceans are shallow relative to the surface area covered by the oceans.
The ocean is layered by temperature.
The zone of rapid change from warm water to cold water with increasing depth is called the
thermocline.
Because cold water is more dense than warm water, this transition zone is also called the pycnocline.
Warm , shallow parts of the ocean, above the thermocline, is in a state of continuous movement, or
circulation.
The cold, deep part of the ocean is also in a state of continuous circulation.
Oceanographers have been describing the circulation of the ocean, and trying to develop theories to
account for it, for over a hundred years.
The circulation of the upper layer of the ocean is caused mainly by the friction force exerted on the
ocean surface by the wind.
One of the basic principles of physics is that a mass of material moves in a straight line at constant speed
unless it is acted upon by some force.
It takes a force to make a mass of material move in a curved path instead of a straight line.
The force that seems to make the water or the pen point move in a curved path is called the Corilois
force.
Scientists use the word “counterintuitive” for things like this: your intuition tells you one thing, but the
real-world situation shows you something very different.
THE DEEP CIRCULATION OF THE OCEAN
The Structure of the Ocean:
The Oceans can well be described as absolutely deep but relatively shallow.
Typical deep ocean depths are four to five kilometers.
Currents in the Deep Ocean:
Currents exist in the deep ocean worldwide, although these currents are generally much slower than
typical surface currents.
These currents originate by production of very dense ocean surface waters at high latitudes in both the
Northern Hemisphere and the Southern Hemisphere.
The density of the surface waters is increased in two ways: it is cooled, and its salinity is increased by
freezing out of fresh-water ice.
The water then sinks and flows slowly at or near the ocean bottom by circuitous routes to low latitudes.
It then is warmed and rises up slowly to the surface, to be carried by surface currents back to highlatitude areas.
Circulation Cell, Not Convection Cell:
Oceans are both heated and cooled at the surface rather than from beneath.
The key element that drives the deep circulation is vertical mixing through the water column at low
latitudes.
What Causes Vertical Mixing?:
Tides are mainly responsible for the mixing, and therefore the existence of the deep circulation of the
oceans.
It is common misconception that the deep circulation, which is somewhat misleadingly called the
thermohaline circulation, is convection: it is not
Stratification of Water Masses in the Ocean:
Oceans are stratified by density.
The most prominent aspect of this stratification is the presence of a shallow surface layer of warm water
that extends from the equatorial regions into mid-latitudes.
At high latitudes, especially in winter, the cold layer extends all the way to the surface so there is no
thermocline.
The densest water in the ocean is produced around the Antarctic continent, especially in winter, by
chilling of the water combined with freezing out of fresh-water surface pack ice, thus increasing the
salinity.
The Difficulties of Studying Ocean Currents:
Objects floating with the currents at depth cannot easily be seen or detected.
Speeds are commonly no more than a few centimeters per second, but under some circumstances per
second, but under some circumstances they can be high as tens of centimeters per second.
It has become clear in recent years as well that the currents are not steady; instead, they fluctuate in
speed and direction on time scales of hours to weeks to years, much as the winds in the atmosphere.
The Effect of the Coriolis Force:
The Coriolis force fundamentally affects the pattern of deep ocean currents.
The water in the oceans can sink, rise, or flow horizontally relative to the surrounding water.
The horizontal movements of ocean water are called ocean currents.
Ocean currents carry matter and energy from one part of the ocean to another.
The surface currents flow much faster than the deep currents, but the deep currents affect a much
greater thickness of the ocean.
The movement of deep ocean water is controlled by the density of the water.
The density of seawater is determined by two factors: temperature and SALINITY.
Salinity is dissolved salts in seawater.
The higher the salinity of ocean water is, the more dense the water is.
When the salinity of a mass of water is increased, the water sinks relative to surrounding masses of
water.
Both are important, although temperature has a much greater effect than salinity on seawater density.
Temperature- The Sun heats the Earth’s surface unequally, because the Sun’s rays strike the Earth from
nearly overhead at low latitudes but at a very low angle at high latitudes.
Because ocean water at high latitudes is also very cold, it is the most dense water in the worlds ocean.
The ocean is a single body of water, but it is not the same everywhere.
Both the temperature and the salinity of ocean water vary from place to place.
Large regions of the ocean have water with about the same temperature and salinity, these are called
water masses.
Water masses are named from where they are formed.
Antarctic Bottom Water is the most dense of all deep ocean water masses.
These slow movements of the deep water masses from a gigantic and very complicated circulation cell
that can take almost 1500 years to complete its cycle.
This deep ocean circulation of the ocean might also be caused by the moon.
THE SURFACE CIRCULATION OF THE OCEAN
Surface Currents: The Ekman Drift:
The frictional forces exerted by the wind produce surface currents.
The highly counterintuitive result is that the net transport of water is at right angles to the wind
direction!
This is called the Ekman Drift.
This represents a balance among three forces: the downward force of the wind; the Coriolis force; at
right angles to the motion; and friction by the underlying water; acting opposite to the direction of
movement.
The phenomenon of the Ekman drift applies to long-sustained winds over areas of the ocean surface.
The frictional forces exerted by the wind produce surface currents.
Surface Currents: Gyres:
One of the most prominent features of the pattern of surface ocean currents is the existence of large
rotatory currents, called gyres, in the ocean basins.
Floating Sneakers example for proof.
The surface currents in the oceans account for almost half of the necessary transfer of heat. If there
were no ocean surface currents, the atmospheric circulation would have to transfer more heat, resulting
in a greater contrast in temperature between low latitudes and high latitudes.
Currents at ocean depths down to 200 meters encompass about 10% of the water in the oceans.
These currents flow for long distances across the oceans.
They form enormous circulation cells, called gyres.
These gyres circulates clockwise in the ocean basins of the Northern Hemisphere and counterclockwise
in the ocean basins of the Southern Hemisphere.
The gyres play a very important part in the Earth’s climate, because they help to transport heat energy
from low latitudes, where the Earth is warmed by the Sun, to high latitudes, where the Earth’s surface
loses heat to outer space.
Easterlies(winds) blow from the East.
Easterlies push water to the West and Westerlies push water to the East.
Water moves in the oceans because it is acted upon by forces.
The overall, movement of the water is at right angles (90 degrees) to the direction of the wind.
The direction of the current is to the right of the wind in the Northern Hemisphere and to the left of the
wind in the Southern Hemisphere.
The surface Ekman drift causes the easterly trade winds to move water towards higher latitudes and
causes the westerlies to move water towards lower latitudes.
Upwelling is the upward movement of ocean water to the surface from deep in the ocean.
As the water at the surface is pushed offshore, water from deeper down has to rise up to replace it.
Everywhere in the oceans, even at low latitudes, the ocean is cold below the surface layer.
Very near the Equator, where the Coriolis effect vanishes, winds blowing directly offshore cause
upwelling, in just the way your intuition might suggest to you.
At higher latitudes, however, offshore winds move water only along coasts, not away from them.
Upwelling supports about half of the world’s fisheries, even though these cool waters account for only
10 present of the surface area of the world ocean.
If the wind blows in the opposite direction, surface Ekman drift would then sink down under the added
weight and be replaced by a surface flow of offshore water. This is the opposite of upwelling and is
called downwelling.
EL NINO AND OCEAN CIRCULATION
Satellite Technology
TOPEX satellite measures more than just the El Nino phenomenom.
Among its roles, it also keeps track of tides, global climate change, variations in currents, large scale
eddies, and effects on marine life.
El Nino
El Nino is associated with changes in both atmospheric pressure and prevailing winds.
El Nino involves changes in ocean circulation, sea surface temperatures, and climate throughout the
entire equatorial Pacific.
WEATHER, CLIMATE, AND EL NINO
El Nino’s Effect on the United States
El Nino had several major consequences for weather in the United States, areas with pronounced aboveaverage precipitation are likely to have and had floods during the year.
Areas with below-average precipitation are likely to have had droughts and water-supply problems.
Areas with warmer-than-usual weather had more rain and less snow cover, or more ice storms.
El Nino and Jet Streams
Teleconnections: effects on weather and climate that manifest themselves far away from the lowlatitude Pacific, where El Nino occurs.
Jet-stream are responsible for steering weather systems across the United States, and they determine
the speed and extent to which cold Arctic air masses can intrude southward into the United States.
Jet streams are closely associated with the prominent boundry between cold, dry air masses from the
north and warm, humid air masses from the south, called the polar front.
El Nino and Offshore Water Temperature
Changing jet-stream patterns result in associated changes in temperature and precipitation.
El Nino can change weather is by changing temperature of the water offshore.
Warming air never causes precipitation.
During El Nino, however, water off the coast of California are warmer than normal , causing the crossing
winds to be warmed and to become more himid.
This warmer moist air tends to produce rain as it moves inland, because it is often warmer than the
California land mass.
This can result in severe floods, mudslides, and other weather-related problems.
Hurricanes and Cyclones
Upper winds blow away cloud tops, preventing full vertical low-pressure development, thus disrupting
hurricane evolution and lowering the frequency of large hurricanes.
La Nina
If El Nino represents above-average ocean water temperatures, then below-average conditions must
also occur.
La Nina conditions, weather patterns are the opposite of El Nino and result n cold and dry weather in
southern California.
Droughts often occur in the Midwest and the Southwest.
Hurricanes tend to reach their greatest strength during La Nina conditions.
Weather is what the atmospheric conditions are like at a particular time, day to day.
Climate is the long term average of weather is a particular region of the Earth, over years, decades, or
centuries.
Teleconnections is used by climatologists for the effects that climate change in one region of the Earth
have on the climate distant regions.
During El Nino years, the jet stream changes its pattern.
Some El Nino events are strong and weak.
Farmers and government officials can use El Nino forecasts to decide on the appropriate combination of
crops to plant.
EL NINO AND THE OCEANIC FOOD CHAIN
Satellite technology has come into its own in identifying regions rich with phytoplankton but not always
the attending anchovies, which are one step up on the food chain.
El Nino causes disruption to the entire food chain, up through and including marine mammals.
Humans are at the top of the food chain, and this is how El Nino can have a great effect on our food
chain.
Anchovy fisherys are sustained by upwelling.
Upwelling is caused by winds that create a surface current that flows offshore.
The upwelled nutrients promote the growth of phytoplankton, which inturn, provide food for
zooplankton, such as copepods, arrow worms, fish larvae, and other small marine animals.
The upwelling brings warm water rather than cold water to the surface.
The higher the surface temperatures force the fish located in coastal areas to migrate north and south in
search of cooler waters and food.
Most fish, not able to migrate, die from lack of food or the increase in temperature.
Those that are able to move north and south do not fare much better.
These fish find themselves in unusually cold waters in which many cannot survive.
Torrential rains greatly increase river discharge, which brings with it large amounts of sediment and
fresh water to the ocean.
Minute plants are known as phytoplankton and zooplankton are tiny animals.
Phytoplankton , which consist mainly of algae, convert the energy of the Sun into matter.
Besides acting as the first link in the food chain, phytoplankton are a critical part of ocean chemistry.
The carbon dioxide in the atmosphere is in balance with carbon dioxide in the ocean.
During photosynthesis, phytoplankton remove carbon dioxide from seawater and release oxygen as a
byproduct.
This allows the oceans to absorb additional carbon dioxide from the atmosphere.
If fewer phytoplankton existed, atmospheric carbon dioxide would increase.
An El Nino event that reduces the abundance of phytoplankton can have global effect because it causes
a change in the amount of carbon dioxide being removed from the atmosphere.
Download