Post on 11-May-2015
Chapter 9.6Finding the formula of a
Compound
How can we work out the formula of a compound?
We can conduct experiments to find out the formula of a
compound.
1. First, we find out the mass of the reactants taking
part in the reaction.
2. Next, we work out the relative numbers of moles of
the reactants used.
Example: Working Out the Formula of Magnesium
OxideTo work out the formula of magnesium oxide produced by the combustion of magnesium, the following apparatus is used.
Magnesium ribbon
Clay triangle
Tripod stand
lid
crucible
Magnesium ribbon
Clay triangle
Tripod stand
lid
crucible
Procedure 1. Weigh a crucible together with the lid. Put a coil of magnesium ribbon in it and weigh again.
2. Put the lid on the crucible and heat the crucible gently. When the magnesium catches fire (you will see a white glow through the crucible), heat it more strongly.
Magnesium ribbon
Clay triangle
Tripod stand
lid
crucible
3. Use a pair of tongs to lift the lid slightly from time to time to allow air in. Quickly replace the lid to make sure that magnesium oxide formed does not escape.
4. When the burning is complete, allow the crucible to cool completely. Weigh the crucible together with the lid and the magnesium oxide in it.
Sample resultsMass of crucible + lid = 26.52 gMass of crucible + lid + magnesium = 27.72 gMass of crucible + lid + magnesium oxide = 28.52 g
CalculationsMass of magnesium = 27.72 − 26.52 = 1.20 gMass of magnesium oxide produced = 28.52 − 26.52 = 2.00 gMass of oxygen reacted = 2.00 − 1.20 = 0.80 g
Deriving the FormulaElement Mg O
Mass (from experiment) 1.20 g 0.80 g
Relative atomic mass 24 16
Number of moles
Molar ratio (divide by the smallest number from the previous row)
1.20
24= 0.05
0.05
0.05= 1
0.05
0.05= 1
0.80
16= 0.05
Step 1: List the mass of the element.
Deriving the Formula
Molar ratio (divide by the smallest number from the previous row)
Number of moles
1624Relative atomic mass
0.80 g1.20 gMass (from experiment)
OMgElement
1.20
24= 0.05
0.05
0.05= 1
0.05
0.05= 1
0.80
16= 0.05Step 2: State the Ar of the element.
Deriving the Formula
Step 3: Derive the number of moles by dividing the mass with Ar.
Molar ratio (divide by the smallest number from the previous row)
Number of moles
1624Relative atomic mass
0.80 g1.20 gMass (from experiment)
OMgElement
1.20
24= 0.05
0.05
0.05= 1
0.05
0.05= 1
0.80
16= 0.05
Step 4: Obtain the molar ratio.
Deriving the Formula
The empirical formula is MgO.
Molar ratio (divide by the smallest number from the previous row)
Number of moles
1624Relative atomic mass
0.80 g1.20 gMass (from experiment)
OMgElement
1.20
24= 0.05
0.05
0.05= 1
0.05
0.05= 1
0.80
16= 0.05
Empirical Formula
• simplest formula of a compound• shows the types of element present
in the compound And
• the simplest ratio of the number of the different type of atoms in it
Worked Example 1
Element Cu OStep 1 Mass of element 8 1Step 2: Ar 64 16Step 3: No. of Moles
(Mass/ Ar)8 = 0.125
64 1 = 0.0625
16
Step 4: Molar ratio (Divide by smallest
number)
0.125 = 2 0.0625
0.0625 = 1 0.0625
A sample of an oxide of copper contains 8g of copper combined with 1g of oxygen. Find the empirical formula of the compound.
Empirical formula of the compound is Cu2O1
or usually written as this Cu2O.
Worked Example 2
• A compound has the following percentage composition: Sodium 32.4 %, Sulphur 22.6%, Oxygen 45.0 %
Element Na S OStep 1 % composition by mass 32.4 22.6 45.0Step 2 Ar 23 32 16Step 3 No. of Moles 32.4 = 1.4
2322.6 = 0.7
32 45.0 = 2.8 16
Step 4 Molar ratio ( divide by smallest number)
1.4 = 2 0.7
0.7 =1 0.7
2.8 = 4 0.7
Empirical formula: Na2SO4
Molecular Formula
Molecular Formula
Its actual formula is P4O10. We call this the molecular formula.
The empirical formula of phosphorus(V) oxide as determined by experiment is P2O5.
Molecular Formula
• shows the exact number of atoms of each element in a molecule
• Is sometimes the same as the empirical formula, i.e. in actual the compound exists in the simplest ratio
• Example: water (H2O) and ammonia (NH3)
Molecular Formula
• However most of the compounds do not have a molecular formula that is similar to the empirical formula.
• If the compound’s molecular formula and empirical formula are different, the molecular formula is just a multiple of the empirical formula
• For example, the molecular formula and empirical formula of phosphorus(V) oxide are P4O10 and P2O5 respectively.
• The multiple is 2.
Molecular Formula
• possible for different compounds to have same empirical formula.
• For example:ethane has a molecular formula of C2H4
propane has a molecular formula of C3H6,
Therefore, they have the same empirical formula which is CH2.
Molecular Formula
• To find the molecular formula of a compound we use this method, n is the multiple to the empirical formula
• n = relative molecular mass of the compound
Mr of the empirical formula
Example 3 Propane has the empirical formula CH2. The relative molecular mass of propane is 42. Find the molecular formula of propane n = relative molecular mass of the compound Mr of the empirical formulan = 42 (12 X 1) + 2 = 3Molecular formular = (Empirical formula ) n
= (CH2)3
Hence the molecular formula for propane is C3H6
= C3H6
Example 4 Compound X contains 40.0% carbon, 6.6% hydrogen and 53.3% oxygen. Its relative
molecular mass is 180. What is the molecular formula of X?
Molar ratio
Number of moles
16112Relative atomic mass
53.36.640.0Percentage in compound
OHCElement
= 3.312
40.0 = 3.316
53.3
= 116
3.52= 2
16
3.52
= 6.61
6.6
= 13.3
3.3
Example 2 (continued)Compound X contains 40.0% carbon, 6.6%
hydrogen and 53.3% oxygen. Its relative molecular mass is 180. What is the molecular formula of X?
The empirical formula of X is CH2O.
=
Mr from empirical formula
Relative molecular mass 180
30= 6
Hence, the molecular formula of X = (CH2O)6 = C6H12O6
Mr of CH2O = 12 + (2 x 1) + 16 = 30
n =