WEBVTT 99:59:59.999 --> 99:59:59.999 In 1992, 99:59:59.999 --> 99:59:59.999 a cargo ship carrying bath toys got caught in a storm. 99:59:59.999 --> 99:59:59.999 Shipping containers washed overboard, 99:59:59.999 --> 99:59:59.999 and the waves swept 28,000 rubber ducks and other toys into the North Pacific. 99:59:59.999 --> 99:59:59.999 But they didn’t stick together. 99:59:59.999 --> 99:59:59.999 Quite the opposite– 99:59:59.999 --> 99:59:59.999 the ducks have since washed up all over the world, 99:59:59.999 --> 99:59:59.999 and researchers have used their paths 99:59:59.999 --> 99:59:59.999 to chart a better understanding of ocean currents. 99:59:59.999 --> 99:59:59.999 Ocean currents are driven by a range of sources: 99:59:59.999 --> 99:59:59.999 the wind, tides, changes in water density, 99:59:59.999 --> 99:59:59.999 and the rotation of the Earth. 99:59:59.999 --> 99:59:59.999 The topography of the ocean floor and the shoreline modifies those motions, 99:59:59.999 --> 99:59:59.999 causing currents to speed up, 99:59:59.999 --> 99:59:59.999 slow down, or change direction. 99:59:59.999 --> 99:59:59.999 Ocean currents fall into two main categories: 99:59:59.999 --> 99:59:59.999 surface currents and deep ocean currents. 99:59:59.999 --> 99:59:59.999 Surface currents control the motion 99:59:59.999 --> 99:59:59.999 of the top 10 percent of the ocean’s water, 99:59:59.999 --> 99:59:59.999 while deep-ocean currents mobilize the other 90 percent. 99:59:59.999 --> 99:59:59.999 Though they have different causes, 99:59:59.999 --> 99:59:59.999 surface and deep ocean currents influence each other 99:59:59.999 --> 99:59:59.999 in an intricate dance that keeps the entire ocean moving. 99:59:59.999 --> 99:59:59.999 Near the shore, 99:59:59.999 --> 99:59:59.999 surface currents are driven by both the wind and tides, 99:59:59.999 --> 99:59:59.999 which draw water back and forth as the water level falls and rises. 99:59:59.999 --> 99:59:59.999 Meanwhile, in the open ocean, wind is the major force behind surface currents. 99:59:59.999 --> 99:59:59.999 As wind blows over the ocean, 99:59:59.999 --> 99:59:59.999 it drags the top layers of water along with it. 99:59:59.999 --> 99:59:59.999 That moving water pulls on the layers underneath, 99:59:59.999 --> 99:59:59.999 and those pull on the ones beneath them. 99:59:59.999 --> 99:59:59.999 In fact, water as deep as 400 meters 99:59:59.999 --> 99:59:59.999 is still affected by the wind at the ocean’s surface. 99:59:59.999 --> 99:59:59.999 If you zoom out to look at the patterns of surface currents all over the earth, 99:59:59.999 --> 99:59:59.999 you’ll see that they form big loops called gyres, 99:59:59.999 --> 99:59:59.999 which travel clockwise in the northern hemisphere 99:59:59.999 --> 99:59:59.999 and counter-clockwise in the southern hemisphere. 99:59:59.999 --> 99:59:59.999 That’s because of the way the Earth’s rotation 99:59:59.999 --> 99:59:59.999 affects the wind patterns that give rise to these currents. 99:59:59.999 --> 99:59:59.999 If the earth didn’t rotate, 99:59:59.999 --> 99:59:59.999 air and water would simply move back and forth 99:59:59.999 --> 99:59:59.999 between low pressure at the equator 99:59:59.999 --> 99:59:59.999 and high pressure at the poles. 99:59:59.999 --> 99:59:59.999 But as the earth spins, 99:59:59.999 --> 99:59:59.999 air moving from the equator to the North Pole is deflected eastward, 99:59:59.999 --> 99:59:59.999 and air moving back down is deflected westward. 99:59:59.999 --> 99:59:59.999 The mirror image happens in the southern hemisphere, 99:59:59.999 --> 99:59:59.999 so that the major streams of wind 99:59:59.999 --> 99:59:59.999 form loop-like patterns around the ocean basins. 99:59:59.999 --> 99:59:59.999 This is called the Coriolis Effect. 99:59:59.999 --> 99:59:59.999 The winds push the ocean beneath them into the same rotating gyres. 99:59:59.999 --> 99:59:59.999 And because water holds onto heat more effectively than air, 99:59:59.999 --> 99:59:59.999 these currents help redistribute warmth around the globe. 99:59:59.999 --> 99:59:59.999 Unlike surface currents, 99:59:59.999 --> 99:59:59.999 deep ocean currents are driven primarily by changes in the density of seawater. 99:59:59.999 --> 99:59:59.999 As water moves towards the North Pole, 99:59:59.999 --> 99:59:59.999 it gets colder. 99:59:59.999 --> 99:59:59.999 It also has a higher concentration of salt, 99:59:59.999 --> 99:59:59.999 because the ice crystals that form trap water while leaving salt behind. 99:59:59.999 --> 99:59:59.999 This cold, salty water is more dense, 99:59:59.999 --> 99:59:59.999 so it sinks, 99:59:59.999 --> 99:59:59.999 and warmer surface water takes its place, 99:59:59.999 --> 99:59:59.999 setting up a vertical current called thermohaline circulation. 99:59:59.999 --> 99:59:59.999 Thermohaline circulation of deep water and wind-driven surface currents 99:59:59.999 --> 99:59:59.999 combine to form a winding loop called the Global Conveyor Belt. 99:59:59.999 --> 99:59:59.999 As water moves from the depths of the ocean to the surface, 99:59:59.999 --> 99:59:59.999 it carries nutrients that nourish the microorganisms 99:59:59.999 --> 99:59:59.999 which form the base of many ocean food chains. 99:59:59.999 --> 99:59:59.999 The global conveyor belt is the longest current in the world, 99:59:59.999 --> 99:59:59.999 snaking all around the globe. 99:59:59.999 --> 99:59:59.999 But it only moves a few centimeters per second. 99:59:59.999 --> 99:59:59.999 It could take a drop of water a thousand years to make the full trip. 99:59:59.999 --> 99:59:59.999 However, rising sea temperatures are causing the conveyor belt 99:59:59.999 --> 99:59:59.999 to seemingly slow down. 99:59:59.999 --> 99:59:59.999 Models show this causing havoc with weather systems 99:59:59.999 --> 99:59:59.999 on both sides of the Atlantic, 99:59:59.999 --> 99:59:59.999 and no one knows what would happen if it continues to slow 99:59:59.999 --> 99:59:59.999 or if it stopped altogether. 99:59:59.999 --> 99:59:59.999 The only way we’ll be able to forecast correctly and prepare accordingly 99:59:59.999 --> 99:59:59.999 will be to continue to study currents and the powerful forces that shape them.