Final volume of a falling droplet

AI Thread Summary
Falling droplets do not have a final volume like falling bodies have a final velocity; their volume remains constant due to the incompressibility of liquids. However, evaporation can occur during the fall, influenced by temperature and humidity. The discussion specifically mentions the final volume of a semen droplet falling from a height of 1 km, noting that while the droplet may change shape, its volume will not significantly decrease unless evaporation is considered. Larger droplets, such as those formed from a cubic kilometer of water, may break apart during the fall but can still maintain a considerable size. Ultimately, the final volume of a droplet depends on various factors, including the liquid's properties and environmental conditions.
eng442
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First of all, do falling droplets have a final volume like falling bodies have a final velocity - in air?

If so, is there a way to determine such volume for a specific liquid and a specific height? More specifically, the final volume of a semen droplet falling from a 1km height.
 
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welcome to pf!

hi eng442! welcome to pf! :smile:

water is, for all practical purposes, incompressible

so (although the shape may change) the volume will be constant :wink:
 
eng442 said:
<snip>More specifically, the final volume of a semen droplet falling from a 1km height.

Eh?

There will be some evaporation, but that depends on the details- temperature(s), relative humidity, etc..

Odd question...
 
eng442 said:
First of all, do falling droplets have a final volume like falling bodies have a final velocity - in air?

If so, is there a way to determine such volume for a specific liquid and a specific height? More specifically, the final volume of a semen droplet falling from a 1km height.

I have never seen rain drops the size of breasts, even small breasts, though possibly the size of a nipple. So yes, if you could form a very large drop of water, say the size of your typical breast then after falling for a kilometer the large drop would break apart towards some maximum size. If on the other hand you had a cubic kilometer of water and could drop it a distance of one kilometer, all at once, I think you might have some very large drops?
 

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