needingtoknow said:
Let's compare natural aluminium (aluminium atoms have an average mass of 26.98 amu) and natural antimony (antimony atoms have an average mass of 121.8 amu). There are two samples, one of each element. The mass of the first sample (aluminium) is 26.8 g and the mass of the second sample (antimony) is 121.8 g. Because the ratio of the sample masses (26.98 g/121.8 g) is equal to the ratio of the masses of the components (atoms) involved (26.98 amu/121.8 amu) theoretically they should have the same number of components (atoms). Now what is the next step to determining the number of components involved? (I know the rule states that it's 6.02 x 10^23, but I want to know the reasoning behind why)
Yes that's right now. Those two samples contain the same number of atoms, one of aluminium, the other of antimony. The way this was known originally had nothing to do with this 6.02 x 10^23 not known till a lot later - rather it was the chemical
combining weight. Aluminium (Al) combines with oxygen ("forms an oxide") and does also with antimony (Sb) and the of Al combines with the same amount (grams) of oxygen as does 121.8 g of Sb. And then the same combining ratios will be found in other compounds e.g. Aluminium sulphate bowever much sulphate (SO
4) is combined with 26.98 g Al,
the same amount of sulfate is combined with 121.8 g of Sb. And these non-trivial and experimentally found consistencies of ratios are very naturally explained by simple atomic theory.
The actual amount of oxygen in aluminium oxide can be calculated from the molecular formula Al
2O
3 and the atomic masses so 26.98 X 2 g Al combines with 16 X 3 g O and so does 121.8 g of Sb.
Etc. for other compounds.
So traditional chemistry, and most chemical laboratory calculations today, are about chemical combining ratios. They would be exactly the same calculations with the same exact numbers if the absolute masses of the atoms or the Avogadro number were a thousand or a million times bigger or smaller.
About the Avogadro number I haven't time this morning but others have said it, I want to come back later too.