Drafting is used to reduce wind resistance and is seen most commonly in bicycle racing, car racing, and speedskating, though drafting is occasionally used even in cross-country skiing and running. Some forms of triathlon allow drafting. Drafting occurs in swimming as well, both in open-water races (occurring in natural bodies of water) and in traditional races in competition pools. In a competition pool, a swimmer may hug the lane line that separates him/her from a swimmer of whom s/he is abaft, thereby taking advantage of the liquid slipstream in the other swimmer's wake.
In cycling, the main (largest) group of tightly packed cyclists in a race is called a peloton, while cyclists riding in straight-line formation, each (but the first) drafting behind the one in front of him, is called a paceline.
Drafting can be cooperative, in which several competitors take turns in the lead position (which requires the most effort and energy consumption). Or, it can be competitive or tactical, where one competitor will try to stay closely behind another leaving him or her more energy for a break-away push to the finish line.
Cooperative fluid dynamics techniques like drafting are found in nature, as well. Flocks of geese and some other birds fly in a V formation because the tip vortices generated by the front bird will create up-wash circulations. (see wingtip vortices) The birds flying behind will receive lift force from these up-wash vortices. Thus, the other birds in the pack won't have to work as hard since studies show they place themselves roughly at the optimum distance predicted by simple aerodynamic theory. The theory behind this is the same as the one for the wings of an airplane in general. However, it does not work quite the same way as drafting in racing. Birds fly in a flock for better lifting force, whereas the race cars stay close for less total aerodynamic drag force.
Goose flocking is not fully understood, but probably involves the recovery of energy from vortices created by the leading birds' wingtips (see wingtip vortices). (For this reason, it may not meet some people's definition of drafting).
Other animals have been observed to use true drafting behavior reminiscent of auto racing or cycling. Lobsters, for example, are known to migrate in close single-file formation "lobster trains", sometimes for hundreds of miles.
On the faster speedways and superspeedways used by NASCAR, ARCA, and the IROC series, two or more vehicles can race faster when lined up front-to-rear than a single car can race alone. The low-pressure wake behind a group's leading car reduces the aerodynamic resistance on the front of the trailing car, allowing the second car to pull closer. As the second car nears the first, it pushes high-pressure air forward so less fast-moving air hits the lead car's spoiler. The result is less drag for both cars, allowing faster speeds.
Handling in corners is affected by balance changes caused by the draft: The leading car has normal front downforce but less rear downforce. The trailing car has less front downforce but normal rear downforce. A car with drafting partners both ahead and behind will lose downforce at both ends.
The "slingshot pass" is the most dramatic and widely noted maneuver associated with drafting. A trailing car (perhaps pushed by a line of drafting cars) uses the lead car's wake to pull up with maximum momentum at the end of a straightaway, enters a turn high, and turns down across the lead car's wake. The combination of running downhill and running across the zone of lowest aerodynamic drag allows the trailing car to carry extra speed and pass on the inside of leader.
Drafting was discovered by stock car racers in the 1959 Daytona 500. Drivers found they picked up speed running closely behind other cars, and as they experimented they found that a line of cars could sustain higher speeds than a single car running by itself.
Drafting is most important at Talladega Superspeedway and Daytona International Speedway where a restrictor plate is used, making much less power available to push the large bodies through the air. Race cars reach their highest speeds on these superspeedways, so the aerodynamic forces are highest, and the effects of drafting are strongest. Since restrictor plates were first used as a safety device, their effect has changed the nature of drafting. Vehicles no longer have sufficient horsepower to maintain their drafting speeds upon exiting the draft. This negates the slingshot maneuver. As a result, passing is often the result of cooperation between two or more drivers.