Ocean Currents Why is Ocean Circulation Important Transport

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Ocean Currents

Ocean Currents

Why is Ocean Circulation Important? • Transport ~ 20% of latitudinal heat – Equator

Why is Ocean Circulation Important? • Transport ~ 20% of latitudinal heat – Equator to poles • Transport nutrients and organisms • Influences weather and climate

Non-rotating Earth Convection cell model

Non-rotating Earth Convection cell model

Add rotation and add landmasses unequal heating and cooling of the Earth

Add rotation and add landmasses unequal heating and cooling of the Earth

Physical properties of the atmosphere: Density • Warm, low density air rises • Cool,

Physical properties of the atmosphere: Density • Warm, low density air rises • Cool, high density air sinks • Creates circular- moving loop of air (convection cell)

Physical properties of the atmosphere: Water vapor • Cool air cannot hold much water

Physical properties of the atmosphere: Water vapor • Cool air cannot hold much water vapor, so is typically dry • Warm air can hold more water vapor, so is typically moist • Water vapor decreases the density of air

Physical properties of the atmosphere: Pressure

Physical properties of the atmosphere: Pressure

90 o 60 o High pressure, dry climate Low pressure, wet climate High pressure,

90 o 60 o High pressure, dry climate Low pressure, wet climate High pressure, dry climate 30 o 0 o 30 o 60 o 90 o ITCZ intertropical convergence zone= doldrums Low pressure, wet climate

The Coriolis effect • The Coriolis effect – Is a result of Earth’s rotation

The Coriolis effect • The Coriolis effect – Is a result of Earth’s rotation – Causes moving objects to follow curved paths: • In Northern Hemisphere, curvature is to right • In Southern Hemisphere, curvature is to left – Changes with latitude: • No Coriolis effect at Equator • Maximum Coriolis effect at poles

The Coriolis effect on Earth • As Earth rotates, different latitudes travel at different

The Coriolis effect on Earth • As Earth rotates, different latitudes travel at different speeds • The change in speed with latitude causes the Coriolis effect

North Pole Buffalo moves 783 mph Quito moves 1036 mph Buffalo 15 o r

North Pole Buffalo moves 783 mph Quito moves 1036 mph Buffalo 15 o r equato N Quito South Pole eq ua Buffalo 79 o. W to r Quito

A) Idealized winds generated by pressure gradient and Coriolis Force. B) Actual wind patterns

A) Idealized winds generated by pressure gradient and Coriolis Force. B) Actual wind patterns owing to land mass distribution. .

Ocean Currents Surface Currents The upper 400 meters of the ocean (10%). Deep Water

Ocean Currents Surface Currents The upper 400 meters of the ocean (10%). Deep Water Currents Thermal currents (90%)

Surface Currents Forces 1. Solar Heating (temp, density) 2. Winds 3. Coriolis

Surface Currents Forces 1. Solar Heating (temp, density) 2. Winds 3. Coriolis

Wind-driven surface currents

Wind-driven surface currents

Wind-Driven and Density-Driven Currents • Wind-driven currents occur in the uppermost 100 m or

Wind-Driven and Density-Driven Currents • Wind-driven currents occur in the uppermost 100 m or less • Density differences causes by salinity and temperature produce very slow flows in deeper waters.

Sailors have know about ocean currents for centuries Sailors have know that “rivers” flow

Sailors have know about ocean currents for centuries Sailors have know that “rivers” flow in the seas since ancient times. They used them to shorten voyages, or were delayed by trying to stem them. If navigators do not correct to deflection by currents, they may be far away from where they think they are and meet disaster.

Ben Franklin and the Gulf Stream

Ben Franklin and the Gulf Stream

Matthew Fontaine Maury The first systematic study of currents was done by Maury based

Matthew Fontaine Maury The first systematic study of currents was done by Maury based on logbooks in the US Navy’s Depot of Charts and Instruments. His charts and “Physical Geography of the Sea” assisted navigators worldwide. http: //www. npg. si. edu/exh/brady/gallery/97 gal. html

Winds and surface water • Wind blowing over the ocean can move it due

Winds and surface water • Wind blowing over the ocean can move it due to frictional drag. • Waves create necessary roughness for wind to couple with water. • One “rule of thumb” holds that wind blowing for 12 hrs at 100 cm per sec will produce a 2 cm per sec current (about 2% of the wind speed)

Top-down drag • Wind acts only on the surface water layer. • This layer

Top-down drag • Wind acts only on the surface water layer. • This layer will also drag the underlying water, but with less force. • Consequently, there is a diminution of speed downward. • Direction of movement is also influenced by the Coriolis Effect and Ekman Spiral

Ekman spiral describes the speed and direction of flow of surface waters at various

Ekman spiral describes the speed and direction of flow of surface waters at various depths • Factors: – Wind – Coriolis effect

Ekman transport is the overall water movement due to Ekman spiral • Ideal transport

Ekman transport is the overall water movement due to Ekman spiral • Ideal transport is 90º from the wind • Transport direction depends on the hemisphere

Ekman Transport Water flow in the Northern hemisphere- 90 o to the right of

Ekman Transport Water flow in the Northern hemisphere- 90 o to the right of the wind direction Depth is important

Currents in the “Real” Ocean Currents rarely behave exactly as predicted by these theoretical

Currents in the “Real” Ocean Currents rarely behave exactly as predicted by these theoretical explanations due to factors such as • Depth—shallow water does not permit full development of the Ekman spiral • Density—deeper currents moving in different directions influence the overlying surface movement

Geostrophic Flow Surface currents generally mirror average planetary atmospheric circulation patterns

Geostrophic Flow Surface currents generally mirror average planetary atmospheric circulation patterns

Current Gyres are large circular-moving loops of water Five main gyres (one in each

Current Gyres are large circular-moving loops of water Five main gyres (one in each ocean basin): • North Pacific • South Pacific • North Atlantic • South Atlantic • Indian • Generally 4 currents in each gyre • Centered about 30 o north or south latitude

Geostrophic flow and western intensification • Geostrophic flow causes a hill to form in

Geostrophic flow and western intensification • Geostrophic flow causes a hill to form in subtropical gyres • The center of the gyre is shifted to the west because of Earth’s rotation • Western boundary currents are intensified Figure 7 -7

Western intensification of subtropical gyres • The western boundary currents of all subtropical gyres

Western intensification of subtropical gyres • The western boundary currents of all subtropical gyres are: – Fast – Narrow – Deep • Western boundary currents are also warm • Eastern boundary currents of subtropical gyres have opposite characteristics

Boundary Currents in the Northern Hemisphere Type of Current General Features Speed Special Features

Boundary Currents in the Northern Hemisphere Type of Current General Features Speed Special Features Western boundary Currents Gulf Stream, Kuroshio warm narrow deep swift sharp boundary w/coastal circulation, little coastal upwelling Eastern Boundary Currents California, Canary cold broad shallow slow diffuse boundaries separating from coastal currents, coastal upwelling common

Pacific Ocean surface currents

Pacific Ocean surface currents

“Hills and Valleys” in the Ocean • A balance between the Ekman transport and

“Hills and Valleys” in the Ocean • A balance between the Ekman transport and Coriolis effect produces “hills” in the center of the gyres and “valleys” elsewhere • Gravitational effects from sea floor features also produce variations in sea surface topography http: //earth. usc. edu/~stott/Catalina/Oceans. html

What do Nike shoes, rubber ducks, and hockey gloves have to do with currents?

What do Nike shoes, rubber ducks, and hockey gloves have to do with currents?

Lost at Sea

Lost at Sea

Duckie Progress • January 1992 - shipwrecked in the Pacific Ocean, off the coast

Duckie Progress • January 1992 - shipwrecked in the Pacific Ocean, off the coast of China • November 1992 - half had drifted north to the Bering Sea and Alaska; the other half went south to Indonesia and Australia • 1995 to 2000 - spent five years in the Arctic ice floes, slowly working their way through the glaciers 2001 - the duckies bobbed over the place where the Titanic had sunk • 2003 - they were predicted to begin washing up onshore in New England, but only one was spotted in Maine • 2007 - a couple duckies and frogs were found on the beaches of Scotland southwest England.

2004 -2007 Barber’s Point

2004 -2007 Barber’s Point

North Pacific Subtropical Gyre • “Great Pacific Garbage Patch” • Estimate: 46, 000 pieces

North Pacific Subtropical Gyre • “Great Pacific Garbage Patch” • Estimate: 46, 000 pieces of floating garbage/mi 2.

North Pacific Subtropical Gyre 135° to 155°W and 35° to 42°N

North Pacific Subtropical Gyre 135° to 155°W and 35° to 42°N

North Pacific Subtropical Gyre Great Pacific Garbage Patch- Good Morning America 2010 http: //www.

North Pacific Subtropical Gyre Great Pacific Garbage Patch- Good Morning America 2010 http: //www. youtube. com/watch? v=u. Lr. VCI 4 N 67 M&feature=player_embedded http: //marinedebris. noaa. gov/info/patch. html#6

Eddy A circular movement of water formed along the edge of a permanent current

Eddy A circular movement of water formed along the edge of a permanent current In an average year, 10 -15 rings are formed 150 -300 km in diameter Speed 1 m/sec Warm core ring 1. Rotates clockwise 2. Found on the landward side of the current Cold core ring (cyclonic eddy) 1. Rotates counterclockwise 2. Forms on the ocean side of the current

Sargasso Sea

Sargasso Sea

Upwelling and downwelling Vertical movement of water ( ) – Upwelling = movement of

Upwelling and downwelling Vertical movement of water ( ) – Upwelling = movement of deep water to surface • Hoists cold, nutrient-rich water to surface • Produces high productivities and abundant marine life – Downwelling = movement of surface water down • Moves warm, nutrient-depleted surface water down • Not associated with high productivities or abundant marine life

upwelling downwelling

upwelling downwelling

Langmuir Circulation

Langmuir Circulation

Satellite Observations • TOPEX/Poseidon, Jason 1, and other satellites have observed patterns of change

Satellite Observations • TOPEX/Poseidon, Jason 1, and other satellites have observed patterns of change over the past few years • Animation of seasonal and climaticallyinfluence shifts available at http: //seawifs. gsfc. nasa. gov/OCEAN_PLANET/MOVIES /Topex_Dynamic_Ocean_Topography. mpg

El Niño-Southern Oscillation (ENSO) • El Niño = warm surface current in equatorial eastern

El Niño-Southern Oscillation (ENSO) • El Niño = warm surface current in equatorial eastern Pacific that occurs periodically around Christmastime • Southern Oscillation = change in atmospheric pressure over Pacific Ocean accompanying El Niño • ENSO describes a combined oceanicatmospheric disturbance

El Niño • Oceanic and atmospheric phenomenon in the Pacific Ocean • Occurs during

El Niño • Oceanic and atmospheric phenomenon in the Pacific Ocean • Occurs during December • 2 to 7 year cycle Sea Surface Temperature Atmospheric Winds Upwelling

Normal conditions in the Pacific Ocean

Normal conditions in the Pacific Ocean

El Niño conditions (ENSO warm phase)

El Niño conditions (ENSO warm phase)

La Niña conditions (ENSO cool phase; opposite of El Niño)

La Niña conditions (ENSO cool phase; opposite of El Niño)

Non El Niño 1997

Non El Niño 1997

Non El Niño upwelling El Niño thermocline

Non El Niño upwelling El Niño thermocline

El Niño events over the last 55 years El Niño warmings (red) and La

El Niño events over the last 55 years El Niño warmings (red) and La Niña coolings (blue) since 1950. Source: NOAA Climate Diagnostics Center

World Wide Effects of El Niño • Weather patterns • Marine Life • Economic

World Wide Effects of El Niño • Weather patterns • Marine Life • Economic resources El Nino Animation http: //esminfo. prenhall. com/science/geoanimations/ani mations/26_Nino. Nina. html

Effects of severe El Niños

Effects of severe El Niños

Surface and Deep-Sea Current Interactions Unifying concept: “Global Ocean Conveyor Belt” http: //seis. natsci.

Surface and Deep-Sea Current Interactions Unifying concept: “Global Ocean Conveyor Belt” http: //seis. natsci. csulb. edu/rbehl/Conv. Belt. htm

Heat Transport by Currents • Surface currents play significant roles in transport heat energy

Heat Transport by Currents • Surface currents play significant roles in transport heat energy from equatorial waters towards the poles • May serve as “heat sources” to cooler overlying air, “heat sinks” from warmer • Evaporation and condensation participate in latent heat exchanges

Matter Transport and Surface Currents • Currents also involved with gas exchanges, especially O

Matter Transport and Surface Currents • Currents also involved with gas exchanges, especially O 2 and CO 2 • Nutrient exchanges important within surface waters (including outflow from continents) and deeper waters (upwelling and downwelling) • Pollution dispersal • Impact on fisheries and other resources

Global ocean circulation that is driven by differences in the density of the sea

Global ocean circulation that is driven by differences in the density of the sea water which is controlled by temperature and salinity.

 White sections represent warm surface currents. Purple sections represent deep cold currents

White sections represent warm surface currents. Purple sections represent deep cold currents

What effect does global warming play in thermohaline circulation? http: //www. youtube. com/v/MZbs. Mlr

What effect does global warming play in thermohaline circulation? http: //www. youtube. com/v/MZbs. Mlr 9 WRI? version=3

1 CO 2 fossil fuel combustion 2 Atmospheric and ocean temp 3 4 Subtropical

1 CO 2 fossil fuel combustion 2 Atmospheric and ocean temp 3 4 Subtropical evaporation High latitude precipitation & runoff North Atlantic regional cooling Deep water formation & thermohaline circulation 6 Global climate interconnections Nordic seas salinity & deep convection 5 Potential feedback of increased tropical salinity

Inquiry 1. What is a convection cell? 2. Which direction do currents get deflected

Inquiry 1. What is a convection cell? 2. Which direction do currents get deflected in the Southern Hemisphere? 3. What depth should the water be for an Ekman spiral to occur? 4. How are surface currents created? 5. What is a gyre? 6. How can an El Nino impact upwelling? 7. Coriolis Effect is strongest near the _____?