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And will it cool off faster if you blow across the top of the cup or directly into the coffee?

Does it have to do with the fact that when you blow across the top of the cup the velocity of the air increases which causes an area of low pressure above the cup, resulting in steam from the coffee to be forced up and out of the cup? Or is that not it?

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  • $\begingroup$ Related question $\endgroup$ – Edward Jul 20 '14 at 0:24
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    $\begingroup$ No mention to Feynman's lectures? $\endgroup$ – Andrestand Dec 11 '15 at 14:40
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When a cup of coffee is hot, the air molecules directly above it get hot as well. After some time, they reach equilibrium and no heat transfer (or maybe very little transfer) occurs. By blowing, you disturb that equilibrium and replace the hot air molecules directly above the cup with colder air and therefore create once again a steeper temperature gradient. This fact makes the content of the cup cool faster via forced convection.

See also convective heat transfer

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  • $\begingroup$ So what would be more effective: blowing across the top of the cup or blowing directly at the coffee? Also, does the drop in pressure resulting from an increased air velocity have nothing to do with it? $\endgroup$ – user55757 Jul 20 '14 at 0:13
  • $\begingroup$ This could be of interest. I also suspect pressure differences play very little role, if any at all. $\endgroup$ – Constandinos Damalas Jul 20 '14 at 0:17
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PhotonicBoom is correct in saying that the airflow created by blowing across the top of the coffee will replace the coffee-heated air with cooler air that will absorb more heat from the coffee. It also allows more of the coffee to evaporate (which might seem like a bad thing, but evaporation is simply the hottest molecules becoming gaseous and leaving, so it has the effect of cooling down the coffee) because air can only hold so much water vapor, and it can absorb water vapor more quickly at low humidity levels. By constantly moving the air above the coffee, you are insuring that the humidity will remain low (relatively - your breath is actually fairly humid but still less than the stagnant air above hot coffee).

Blowing into the coffee will cool it more quickly than simply blowing over it because it creates all of the above effects, but it also creates turbulence in the coffee itself, which also cools the coffee. Because the coffee can only evaporate from the top, a majority of the liquid stays pretty well insulated when still, so the only heat transfer from the bottom of the cup to the top is convection, and water has a very high heat capacity so it does not conduct heat very quickly. By blowing into the coffee, you effectively stir the coffee, moving the hottest molecules around so that they all move to the top of the cup and have a chance to escape into the air at some point. The uneven surface also has more surface area than a flat surface, giving even more molecules the chance to escape.

Note: Your breath is actually a pretty poor gas to use to cool down coffee efficiently due to its high temperature and humidity. To maximize efficiency, try to blow from the front of your mouth rather than pushing from your throat. (I don't know how much that makes sense - it's something that musicians are often instructed to do to change their tone. When you blow from the front of your mouth, like you're whistling, the air is cooler and drier than when you breath from the back of your throat, like when you yawn.)

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Boiling point is defined as the temperature at which the vapor pressure directly above the liquid is the same as the pressure of the environment. So, when boiling water in a room at 1 atm, it will begin to boil when the vapor pressure on the surface of the water reaches 1 atm (which is at 100 degrees Celsius). That is why water boils at a lower temperature in the mountains.

By blowing over the hot water, the vapor pressure is lowered/disrupted and the body of water expends energy trying to reestablish the equilibrium between vapor pressures at the corresponding temperature. Consequently, this energy expenditure causes the temperature of the body of water to decrease.

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When we blow air it's temp is about 98.5°F the cup of coffee also heat when more heat a given to coffee its evaporation rate increases and gets cool down quickly

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protected by AccidentalFourierTransform Oct 24 '18 at 2:24

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