1-10: Ocean structure and circulation

Eugene S. Takle
© 1997

Images
figure 1
Major ocean currents.
figure 2
Gulf stream temperature. NASA
figure 3

Ocean flow
figure 4

Relation of the polar front to wind and pressure belts.
figure 5

Conceptual illustration of the Atlantic conveyor belt circulation.
figure 6

Abyssal circulation
figure 7

Density of pure water vs. temperature
figure 8

Strait of Gibraltar.NASA.
figure 9

Tropical Pacific Ocean annual average precipitation. Adapted from R.C. Taylor, 1973: An atlas of Pacific Island rainfall. Hawaii Institute of Geophysics.
figure 10

Depth vs. temperature in tropical, mid-latitude and polar regions
figure 11

Coastal flow in the NH
figure 12

Nutrient rich waters.
figure 13

Euphotic zone.
figure 14

NH
figure 15

SH
figure 16

Northern California
figure 17

Atlas system
figure 18

TOGA system
figure 19

Pacific array

Conduction, Convection, and Radiation
Oceans are critically important in the movement of heat over the planet. In elementary school you learned that heat moves by conduction, convection, and radiation. Radiation and conduction are effective in moving heat vertically from the earth's surface, but are relatively unimportant in moving heat horizontally. Water, like air, is a fluid that can carry heat as it moves from one place to another. Meteorologists have different terms for horizontal and vertical movement of fluids: movement in the vertical direction is called convection, and movement in the horizontal direction is called advection. Convection contributes, with radiation and conduction, to the movement of heat in the vertical direction. But advection is the essentially the sole process by which heat moves laterally over the surface of the earth.

Water Transport of Heat
Water is about 1,000 times as dense as air, and, since the amount of thermal energy transported by a moving fluid is proportional to its density, a volume of water can transport about a thousand times as much heat as an equivalent volume of air. The rate at which heat is transported, called the heat flux, is measured in Joules of energy per unit area per unit time, so the rate at which heat is transported is also proportional to the speed of movement (wind speed in air or current speed in the ocean). Since wind speed is typically of the order of 10 meters per second and ocean drift currents on the order of centimeters per second, the air speed is about a thousand times larger than ocean speed. Therefore, air moves a thousand times faster than water but carries only about 1/1000 as much heat per unit volume, which suggests that water is approximately of equal importance to air in moving heat over the planet.

Ocean Circulation
Figure 1 shows the major movement of water in the oceans of the world. Note the location of the Equator and the general direction of motion in the Northern and Southern Hemisphere. The Southern Hemisphere has major counterclockwise circulation gyres in the South Pacific and South Atlantic Oceans. The Indian Ocean directly west of Australia also has a smaller gyre, with an even smaller circulation pattern in the Arabian Sea and Bay of Bengal to the north. These circulation patterns all conspire to create a west-to-east flow around the rather circular Antarctic continent and a generally east-to-west flow around the equator.
The clockwise circulation patterns in the Northern Hemisphere include a single gyre in the North Atlantic and two cells in the North Pacific Ocean. Above $40$ ^o N, the circulation patterns become more complicated due to interactions with continents and the Arctic Ocean, but where smaller circulations exist, the clockwise rotation is preserved. Note the position and direction of the Gulf Stream off the east coast of the US and the North Atlantic drift current between Greenland and Scandinavia. A close-up satellite picture of the Gulf Stream, with color enhancement to show temperatures, shows the horizontal extent of the warm current and the eddy structure that develops off the New England coast (figure 2).
An interesting consequence of these circulations is that, in both hemispheres, the west coasts of continents generally have flow toward the Equator and east coasts have flow away from the Equator. Other factors being equal, this suggests that west coasts of continents will have slightly cooler water offshore compared to east coasts at the same latitude. In the US, the water off northern California is much colder than off New York, at the same latitude.

Gulf Stream
The Gulf Steam carries warm tropical water off the east coast of the US in a direct path toward Great Britain and the Scandinavian countries, giving these regions a far warmer climate than, say, Alaska which is at a comparable latitude.

Coriolis Force
The rotation in the major ocean basins is driven by a combination of wind stress at the ocean surface and the Coriolis force due to the earth's rotation. As discussed in the lecture on atmospheric structure and circulation, the winds at the earth's surface blow from east to west in at the Equator and generally west to east at the middle latitudes (30 to 60^o north and south of the equator). The wind induces an ocean drift current generally in the same direction but slightly to the right of the wind direction in the Northern Hemisphere and to the left of the wind in the Southern Hemisphere. This is shown in figure 3. The effect of the Coriolis force can be visualized by considering the ocean circulation as seen from the North Pole as in figure 4. The earth rotates as shown by the green arrow. The law of conservation of momentum says that in the absence of forces, the momentum of an object does not change. A parcel of water (or air) that has a component of its velocity toward the Equator (outer boundary of the circle) will be moving to positions at greater distance from the polar axis. Because of the rotation of the earth, the total speed of the parcel will increase (and violate the law of conservation of momentum) unless it moves in the direction opposite to the rotation, as shown, and follows a path that curves to the right. A parcel moving toward the axis of rotation (northward in the Northern Hemisphere) similarly will move in a clockwise direction. For flow south of the Equator, the same reasoning leads to the conclusion that rotation in the Southern Hemisphere is in the counterclockwise direction.
Global Circulation Pattern
Figure 5 gives a conceptual picture of the global circulation pattern that links the major ocean basins of the planet. The large region of open ocean in the Equatorial Pacific allows significant warming of water as it drifts to the west and past the northern edge of Australia. This warm surface water drifts on westward through the Indian Ocean and around the horn of Africa. From here it turns northward, crossing the Equator (taking a more easterly direction than shown here), and creating the Gulf Stream off eastern North America. The warm surface water continually cools as it moves northward past Great Britain and into the Norwegian Sea. By this time the water is sufficiently cold and dense that it sinks to lower depths in the ocean. This creates the start of the global scale return current at low depths that moves southward across the Equator, back around the horn of Africa, past the southern edge of Australia and back to the central Pacific Ocean. A smaller branch of the return current splits off after passing Africa and enters the Indian ocean where sufficient warming augments the warm surface current coming from the central Pacific. Flow in the lower depths of the ocean is shown in figure 6. Of particular note in this graph are the regions of subsidence northeast of Iceland and in the south Atlantic near Antarctica which remove water from the surface and deliver it to deeper levels in the ocean. A third subsidence region of lesser extent exists in the Labrador Sea between Laboratory and Greenland. To understand the reason for these subsidence regions we must examine the driving forces for vertical circulation in the ocean.
Vertical Motions
Vertical motions in the ocean are driven by small differences in water density due to differences in salinity (salt content) and (or) differences in temperature. Increased salt content increases density of water, and generally cold water is more dense than warm water, with one profound exception. Figure 7 describes the density of pure water as a function of temperature. It is apparent that density goes up as temperature decreases from $20$ ^oC on the plot. This trend is terminated, however, at about $4$ ^oC where the curve peaks and indicates that the density of water decreases with temperature below this point. To visualize the impact of this concept, consider an idealized body of water at uniform temperature of $20$ ^oC. When it is cooled at the surface, dense water from the surface will sink to the bottom and be replaced by warmer, less dense water. This process continues until the surface (and hence the entire water body) reaches $4$ ^oC. Any further cooling at the surface creates less dense water at the top which will stay there. Ultimately the surface will freeze if cooling continues, with the lower levels remaining at $4$ ^oC. Fish and bottom-rooted plants therefore are protected from freezing. (Every Canadian fisherperson ought to keep this graph in his/her tackle box as a reminder that lakes in that region support fish because of this peculiar effect!) The ocean does not have a uniform salinity. As ocean water flows toward the polar region from the Equator, it passes the subtropical high-pressure zones that have very little precipitation but intense solar radiation that promotes evaporation. In regions where evaporation is high, the salt content of the remaining surface water increases, thereby increasing the density. The Mediterranean Sea receives relatively low amounts of input from rivers but a large amount of evaporation due to persistent clear skies and intense solar radiation. As a result, very dense water is created in the basin which spills out at the basin bottom at the Strait of Gibraltar, drawing less salty water into the basin at the upper surface. This effect is graphically revealed in figure 8. In regions where precipitation is high, such as the Intertropical Convergence Zone in the central Pacific Ocean shown in the lecture on Atmospheric Structure and Circulation (figure 9), fresh-water rain will ride on top of the saline ocean water. Similarly melting ice in polar regions will be less dense than nearby ocean water of temperature $4$ ^oC because of its lower temperature and lack of salt.
These concepts help of density dependence on temperature and salinity explain the linkage of surface water to the abyssal (deep ocean) circulation. In the North Atlantic water traveling northward at the surface passes through the subtropical high pressure zone and experiences a density increase due to evaporation. As it continues northward, the surface water cools, with further increase in density. Ultimately the density increases to the extent that massive subsidence is created to the north of Iceland. The subsidence region in the Southern Hemisphere is explained for the same reason, since warm water from the tropical Pacific has experienced both evaporation and cooling by the time it reaches the region north of the Weddell Sea (southeast of the southern tip of South America).
Figure 10 shows the effect of vertical temperature profile on mixing at different latitudes. In the tropics, shown in the left graph, surface water is very warm and rides on top of much colder water at depths below 200 m and prohibits vertical mixing. In polar regions, by contrast, cool water formed at the surface has the ability to mix to deep layers or even, with excess salt content, move to the ocean floor and become part of the abyssal horizontal flow pattern. We will return to this production of deep water in polar regions when we discuss sea level rise in Block 2.

Coastal Currents and Land Mass Interactions
The first image of this lecture showed the existence of strong ocean currents along coastlines of continents. The interaction of the coastal currents with the land mass leads to important characteristics of the temperature and biological activity in these regions. Figure 11 shows coastal flow in the Northern Hemisphere with a wind generally from north to south parallel to the west coast of a continent. The Coriolis force provides a force to the right of the wind and tends to transport surface water away from the continent. This lowers sea level slightly near the continent and draws water from deeper levels leading to what we call upwelling. The sloped ocean surface also establishes a force directed toward the continent. Flow resulting from this force also in deflected to the right (in the Northern Hemisphere) further intensifying the southward coastal flow along the continent. A wind from the south on the east coast of a continent in the Northern Hemisphere will have the same effect.
The upwelling along continental coastlines brings nutrient-rich waters (figure 12) from deeper layers into the euphotic zone and promotes rich biological activity (figure 13) as previously shown in satellite pictures of the Northern Hemisphere (figure 14) and Southern Hemisphere (figure 15). A close-up of the California coast shows the abundance phytoplankton off the coast of Northern California (figure 16). Measurements of meteorological and oceanographic data at remote locations in the ocean are made with moored buoys such as the Atlas system (figure 17). During the Tropical Atmosphere/Global Ocean (TOGA) experiment a network of such moored buoys was deployed (figure 18). The Pacific array presently provides real-time measurements of sea-surface temperatures (figure 19). These will be of considerable interest when we begin discussing El Nino. A variety of surface and subsurface ocean data can be accessed online. Data from an oceanographic research ship presently in the TOA array also can be accessed in real time.

Transcription by Theresa M. Nichols