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2024-04-22T03:28:01Z

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[[File:Apollo_15_splashdown.jpg|Apollo 15 splashdown|thumb]] [[Image:Splashdown.png|Splashdown|thumb|left]] [[Image:Splashdown_2.png|Splashdown 2|thumb|left]] [[File:Apollo14_-_Landung.jpg|Apollo14 - Landung|thumb]] [[File:SpaceX_CRS_25_Splashdown_(1920x1080).webm|SpaceX CRS 25 Splashdown (1920x1080)|thumb]] [[File:Apollo_15_descends_to_splashdown.jpg|Apollo 15 descends to splashdown|thumb]] '''Splashdown''' is the method of landing a [[spacecraft]] by parachute in a body of water. It was commonly used by American manned spacecraft during the 20th century, notably in the [[Mercury]], [[Gemini]], and [[Apollo]] programs. The concept of splashdown is rooted in the need for a safe, controlled, and recoverable landing method for returning from space.

==History==
The history of splashdown landings began with the inception of manned spaceflight. The [[Soviet Union]] initially led the space race, opting for land-based returns. However, the United States chose water landings due to the country's extensive naval resources and the perceived lower risk to the astronauts and the public. The first manned spacecraft to make a splashdown was [[Mercury-Redstone 3]], piloted by astronaut [[Alan Shepard]] in 1961.

Throughout the 1960s and early 1970s, splashdowns were the standard method of returning from space. The [[Apollo 11]] mission, which first landed humans on the [[Moon]], concluded with a splashdown in the Pacific Ocean. The last splashdown of the Apollo program was [[Apollo-Soyuz Test Project]] in 1975, marking the end of an era.

==Procedure==
The splashdown procedure begins as the spacecraft re-enters the Earth's atmosphere. The spacecraft is slowed down significantly by atmospheric drag, and a series of parachutes are deployed to reduce its speed further as it approaches the water. The main factors considered in a splashdown include the angle of re-entry, the timing and deployment of parachutes, and the selection of a safe landing area clear of shipping lanes and storms.

==Recovery Operations==
Upon splashdown, recovery operations are immediately initiated. The United States Navy typically played a central role in these operations, deploying aircraft and ships to locate and retrieve the spacecraft and astronauts. The recovery team ensures the astronauts' safety, secures the spacecraft, and transports them back to land for further analysis and debriefing.

==Modern Use==
While splashdowns are less common in the 21st century, with advances in technology allowing for land-based returns, they are still used by some modern spacecraft. Notably, the [[SpaceX]] Dragon capsules have successfully performed splashdowns, demonstrating the method's ongoing viability and safety. These modern splashdowns benefit from advanced technology, including precision tracking and improved materials, making them safer and more reliable than their predecessors.

==Advantages and Disadvantages==
Splashdowns offer several advantages, including the ability to land a larger area, reducing the precision needed in re-entry calculations. Water landings also mitigate some of the risks associated with high-speed landings. However, there are disadvantages, such as the potential for water ingress into the spacecraft, the need for extensive naval recovery operations, and the impact of saltwater on spacecraft components.

==Conclusion==
Splashdowns played a crucial role in the early history of manned spaceflight and continue to be a viable method for returning from space. As space exploration evolves, the techniques and technologies associated with splashdowns and other landing methods will continue to advance, ensuring the safety and success of future missions.

[[Category:Spaceflight]]
[[Category:Astronautics]]
{{spaceflight-stub}}

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