There are also latent heat considerations — water vapor condenses during cloud formation and precipitation events, and
water droplets evaporate when clouds dissipate.
The particles in turn create heat, and
the water droplets evaporate at a faster pace.
When
the water droplets evaporated, they generated a capillary force that crumpled the sheets into miniaturized paper balls.
Not exact matches
When
water droplets hiss and
evaporate immediately, pour batter in 1/4 cup portions into skillet.
In spray - drying, a mixture of
water and the material to be dried is forced through a sprinkler into a high - temperature drum, instantly
evaporating the
water droplets clinging to the material.
As the
water naturally
evaporates, the vapor fills the area in between the pillars below the
droplet, building pressure.
As the mist rises, the
water evaporates from the
droplets to leave the airborne salt crystals.
So as said
droplets of sulfuric acid could in atmospheric pressure of around 1 atm, heat up to 100 C.
Water droplets would never get this hot - but instead would quickly
evaporate at around 30 C [assuming atmosphere was wetter, in dry atmosphere of Venus they
evaporate quickly as ice.
And of course bright white clouds can to reflect more sunlight than the yellowish
droplets of pure sulfuric acid, but the
water clouds also
evaporate.
This wandering is entirely reversible: when there are large
droplets to condense on, temperature equilibrates to the value of T for which
water molecules are condensing on and
evaporating from
droplets in equal numbers, just as in any reversible chemical reaction.
If live near an ocean you get salt corroding everything - so have these
water droplet - not formed from condensation [that would be pure
water and not a problem] but wind and waves mechanically making these
droplets, plus high humidity of general environment preventing them from
evaporating quickly.
Or if the there enough
water molecule in
droplet the
water acts similar to a drop
water from dripping facet or pool of
water - which a portion of it is
evaporating and condensing - but with H20 gas molecules in a gas mixture most of gas molecules are transiting from gas to liquid state within a time frame of something like less than a second.
The heat pipe analogy is more appropriate to the whole hydrological cycle, the essential energetics of which occur at the surface (the hot
evaporating end), in the clouds where the larger
water droplets accelerate condensation, and in precipitation, which converts very slowly acquired potential energy back into kinetic and thermal energy very quickly.
But if one molecule of gas join with
droplet of 1000 or more molecules of
water then it might not
evaporate for many seconds - a
water molecule and many
water molecules may stay as
water molecule for a long period time.