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For more on marking an answer as the "Best Answer", please visit our FAQ.Salt acts as a freezing point depressant. This means that when salt is added to water, the freezing point of the resulting salt brine becomes considerably lower than that of pure water. This salt/water solution freezes at -21.1�C. As you can see, the freezing temperature of Sodium Chloride Brine is much lower than the well-known freezing temperature of water at 0�C. This is why salt is called a freezing point depressant; it lowers the freezing temperature of water...
Using the Fahrenheit scale, water freezes at 32 degrees, brine (salt water) at zero degrees.
When he was working on his thermometer, Fahrenheit couldn't (reliably) get any colder than frozen brine, so he set that as his zero. Having chosen 180 degrees for the difference between the freezing and boiling points of pure water, the freezing point of water became 32 degrees.
Why 180 degrees? probably on account of the number of factors - 2, 3, 4, 5, 6, 9, 10, 12
All right - that's more information than you need! :-)
http://tinyurl.com/5mvkl ...Deja vu, Clanad?
As for how salt melts ice, this has to do with the way salt and water interact with each other on the molecular level.
Water (H2O) and salt (NaCl) are both known as polar molecules. That is to say, the electrons bound to a polar molecule are not shared equally between all the atoms forming that molecule. In a water molecule, there are two hydrogen atoms and a single oxygen atom. The oxygen atom exerts a large "pull" on the six orbiting electrons, while the two hydrogen atoms each exert small pulls. The result is that the electrons orbit closer to the oxygen side of the molecule than the hydrogen side. In salt (NaCl) it is the chlorine atom that pulls the electrons closest.
The side of the molecule that "wins" the electron tug-of-war will gain a slightly negative charge (because electrons are negatively charged). The opposite side of the molecule will gain a small positive charge. These two sides are referred to as "electronegative" and "electropositive" respectively (at least, that is what I call them).
When salt is added to liquid water, the electropositive (hydrogen) ends of the water molecules find themselves strongly attracted to the electronegative (chlorine) ends of the salt molecules. At the same time, the electronegative (oxygen) ends of the water molecules find themselves attracted to the electropositive (sodium) ends of the salt molecules.
[Continued...sorry]
The result is that the NaCl molecules are pulled apart and become surrounded by water molecules. When a NaCl molecule divides in this way, two ions are formed: Na+ and Cl-. (This is understood best by examining a periodic table - sodium is in group 1 and chlorine is in group 7.) See this excellent diagram somebody has made: http://tinyurl.com/59b55 (the red dots are oxygen molecules, beige are hydrogen, blue are sodium and green are chlorine).
Why have I mentioned liquid water? Look at the diagram on the right, which shows salt fully dissolved in water (in reality, not all molecules would be surrounding the dissolved ions - many would be drifting freely as in diagram a). If you wanted to freeze the water now that it has salt in it, what would happen? Normally, at 0�C water molecules are moving slowly enough to line up positive-to-negative and lock in place, forming solid ice. (They have to spread apart a little to achieve this.) When dissolved salt is present, it becomes harder for those water molecules occupied with surrounding the salt ions to join with their neighbouring water molecules and form ice. A lower temperature is required; say, -5�C. Add more salt, and an even lower temperature is required. Dump a load of salt directly onto some ice, and the resulting "pull" of the NaCl on the frozen water may be strong enough to force the water out of its neat, lined-up shape and back into a liquid. More salt will immediately dissolve into the liquid water, and then more ice will be melted, and so on. The process will cease to melt any more ice when the water-salt solution becomes too diluted.