There's a difference between molecular and empirical formulas that you're not understanding
(1) the molecular formula represents all the atoms in the molecule
(2) the empirical formula represents the lowest whole number ratio of
atoms of different elements in a molecule
again,
1 represents the entire molecule
the other represents
the lowest whole number ratio of different elements in the molecule
example the molecule H-O-O-H
molecular formula = H2O2
empirical formula = HO
there are 2 empirical units in every 1 molecule of H-O-O-H
the ratios of H:O are the same in both formulas right? 2:2 = 1:1 ?
but 1 (the molecular formula) indicates the smallest particle of that chemical
and the other represents the lowest whole number ratio of atoms of the 2 elements
example C6H12O6... glucose.. this molecule
https://en.wikipedia.org/wiki/Glucose#/media/File:D-glucose-chain-2D-Fischer.png molecular formula = C6H12O6
empirical formula = CH2O... the lowest whole number ratios of C:H:O in the molecule 1:2:1
there are 6 empirical units per 1 molecule of glucose
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let's try another example
let's say I glue 1 penny to 1 quarter. Then I repeat it 5 times. So I have 5 penny-quarter units.
then let's say I glue all 5 penny-quarter units together into 1 lump. see the attached pic
the total lump is 5 Pennies + 5 Quarters.... let's write that as P5Q5
the lowest whole number ratio of P to Q represents the individual units P1Q1
the lump has "lump value" = $1.30
the individual units have value = $0.26
if I divide $1.30 / $0.26 I get the value "5" meaning there are 5 units in the lump
I can multiple the units x 5 to get the "lump". P1Q1 * 5 = P5Q5
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now let's take this 1 step further. let's say we glue some quarters, dimes, and pennies together
to make a lump with value approximately = $4.00
If we run an analysis, and I tell you that 50.0% of the coins are dimes, 16.7% are quarters and 33.3% are pennies, I could do this:
(1) assume 100 coins
(2) convert percents to coins
(3) simply the ratios of the coins to the smallest unit (empirical coin unit)
(4) divide the total value of the lump by empirical unit value to get # empirical
units in any given lump.
(5) multiply empirical unit by number of empirical units in the lump to the the formula for the lump.
the "empirical unit has"
# dimes = 100 coins * (0.500 dimes / coin) = 50 dimes
# quarters = 100 * 0.093 = 16.7 quarters
# pennies = 100 * 0.349 = 33.3 pennies
now that's not whole numbers (it's hard to glue together 2/3 of a quarter and 1/3 of a penny right?) So lets find the lowest whole number ratio of those coins. We start by dividing all by whichever is the least
# dimes = 50.0 / 16.7 = 3
# quarters = 16.7 / 16.7 = 1
# pennies = 33.3 / 16.7 = 2
and the "empirical" unit is P2QD3 with value = 2*0.01 + 1*0.25 + 3*0.10 = $0.57
the number of empirical units in our lump = $4.00 / $0.57 = 7
the formula of the lump is then 7*P2QD3 = P14Q7D21
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it's the same thing with molecules.. C6H126 with "mass" = 180
lowest ratio = CH2O with mass = 30
so the number of CH2O per molecule = 180 / 30 = 6
and I can write CH2O * 6 = C6H12O6