4 Moles

Question 1

4.4 moles of iron are reacted with excess oxygen. How many moles of oxygen reacted?

Answer 1

Mole ration of Fe to O₂ is 4 : 1

4.4 / 4 = 1.1 moles of oxygen reacts

Question 2

The apparatus below is used to find the empirical formula of magnesium oxide.

2Mg + O₂ –> 2MgO

1. Measure the mass of the crucible + lid
2. Add a coiled piece of magnesium metal
3. Measure the mass of the crucible + lid + magnesium metal
4. Heat the crucible using a roaring flame - be sure to lift the lid every minute and replace it
5. When all the magnesium turns white, turn off the Bunsen burner and allow it to cool
6. Measure the mass of the crucible + lid + Magnesium oxide.
7. Repeat the heating and measuring the mass when cool until constant mass is reached.

How would the mass of oxygen be calculated from the data?

Answer 2

{Mass of crucible + lid + magnesium oxide} - {Mass of crucible + lid+ magnesium}

Question 3

Below is the set up that can be used to work out the formula for the water of crystallisation of copper (II) sulfate.

What measurements must be taken to work out the ratio of CuSO₄ to H₂O at 1 :5?

Answer 3

1. mass of evaporating basin
2. mass of evaporating basin + hydrated copper sulfate - before heating
3. mass of evaporating basin + anhydrous copper sulfate- after heating

Question 4

The apparatus below is used to find the empirical formula of magnesium oxide.

2Mg + O₂ –> 2MgO

1. Measure the mass of the crucible + lid
2. Add a coiled piece of magnesium metal
3. Measure the mass of the crucible + lid + magnesium metal
4. Heat the crucible using a roaring flame - be sure to lift the lid every minute and replace it
5. When all the magnesium turns white, turn off the Bunsen burner and allow it to cool
6. Measure the mass of the crucible + lid + Magnesium oxide.
7. Repeat the heating and measuring the mass when cool until constant mass is reached.

Why is the heating repeated until constant mass is acheived?

Answer 4

To ensure all the magnesium has reacted

Question 5

Below is the set up that can be used to work out the formula for the water of crystallisation of copper (II) sulfate.

The following measurements were taken:

1. mass of evaporating basin
2. mass of evaporating basin + hydrated copper sulfate - before heating
3. mass of evaporating basin + anhydrous copper sulfate- after heating

Why must the crystals be heated until constant mass is reached?

Answer 5

To ensure that all the water has been removed- When all the water has been removed, the mass will no londer change.

Question 6

How is molecular mass different from molar mass (relative formula mass)

Answer 6

Molecular mass is the relative mass of one molecule of a substance measure relative to carbon-12 just like realtive atomic mass is the relative mass of one atom of an element

However, molar mass or relative formula mass is the mass of one mole of that substance measured in g/mol.

Question 7

Rearrange the equation to make mass the subject of the equation

Answer 7

mass = n x RFM

Question 8

What does M_r stand for?

Answer 8

Relative molecular mass- mass of one molecule of a substance compared to 1/12th the mass of a carbon-12 atom and taking into consideration the abundance of the isotopes of the atoms the molecule is made of.

Question 9

Below is an example calculation for the empirical formula of Fe₂O₃

List the steps taken to determine the empirical formula of a substance

Answer 9

1. Calculate the moles of each element
2. Divide by the smallest (1 : 1.5)
3. multiply up to a whole number (2 : 3)
4. Assign the ratio to show the empirical formula (Fe₂O₃)

Question 10

What is a mole?

Answer 10

The measure of amount of substance

Question 11

Below is the set up that can be used to work out the formula for the water of crystallisation of copper (II) sulfate.

The following measurements were taken:

1. mass of evaporating basin
2. mass of evaporating basin + hydrated copper sulfate - before heating
3. mass of evaporating basin + anhydrous copper sulfate- after heating

How can you calculate the mass of water in hydrated copper sulfate?

Answer 11

mass of water = (mass of evaporating basin + hydrated copper sulfate) - (mass of evaporating basin + anydrous copper sulfate)

Question 12

Below is the set up that can be used to work out the formula for the water of crystallisation of copper (II) sulfate.

The following measurements were taken:

1. mass of evaporating basin
2. mass of evaporating basin + hydrated copper sulfate - before heating
3. mass of evaporating basin + anhydrous copper sulfate- after heating

Why must the crystals not be overheated?

Answer 12

To prevent the crystals from reacting and forming other products- only the water must to be removed- over heating may create dangerous fumes which should not be breathed in.

Question 13

Below is the set up that can be used to work out the formula for the water of crystallisation of copper (II) sulfate.

The following measurements were taken:

1. mass of evaporating basin
2. mass of evaporating basin + hydrated copper sulfate - before heating
3. mass of evaporating basin + anhydrous copper sulfate- after heating

How can you calculate the mass of copper sulfate in the sample?

Answer 13

mass of copper sulfate = (mass of evaporating basin + _anhydrous_ copper sulfate) - (mass of evaporating basin)

Question 14

What equation links moles, mass and RFM?

Answer 14

Question 15

What is the mole ratio of methane to chlorine ?

Answer 15

1 : 4

Question 16

What is the mass of one mole of carbon?

Answer 16

12 grams

Question 17

What is water of crystallisation?

Answer 17

It refers to the water molecules that form an essential part of a crystalline structure.

Eg. Copper sulfate has 5 water molecules bound to it

Question 18

Define relative atomic mass (A_r)

Answer 18

The average mass of an atom relative to 1/12th the mass of a carbon-12 atom taking into consideration the abundance of its isotopes.

Question 19

What is molar mass?

Answer 19

The molar mass is the relative formula mass (RFM) of a substance, measured in g/mol

Question 20

What does the symbol A_r stand for?

Answer 20

Relative atomic mass - mass of one atom of an element compared to the 1/12th the mass of an atom of carbon-12 taking into consideration the abundance of its isotopes.

Question 21

The apparatus below is used to find the empirical formula of magnesium oxide.

2Mg + O₂ –> 2MgO

1. Measure the mass of the crucible + lid
2. Add a coiled piece of magnesium metal
3. Measure the mass of the crucible + lid + magnesium metal
4. Heat the crucible using a roaring flame - be sure to lift the lid every minute and replace it
5. When all the magnesium turns white, turn off the Bunsen burner and allow it to cool
6. Measure the mass of the crucible + lid + Magnesium oxide.
7. Repeat the heating and measuring the mass when cool until constant mass is reached.

How would the mass of magnesium be calculated from the data?

Answer 21

{Mass of crucible + lid + magnesium} - {Mass of crucible + lid}= mass of magnesium

Question 22

To find the formula for hydrated crystals such as hydrated copper sulfate the following steps are taken to find the ratio of CuSO₄ to H₂O:

1. Calculate the mass of anhydrous crystal AND mass of water from the experimental data
2. Calculate the number of moles of each by dividing mass by the RFM

What are the last two steps?

Answer 22

3. divide both by the smallest moles value to find the ratio (e.g. 1 : 5)
4. assign the empirical formula (e.g. CuSO₄ •5H₂O)

Question 23

Find the molecular formula of a substance with a relative formula mass of 87 and an empirical formula of C₂H₅

Answer 23

RFM of C₂H₅ = 12+12+1+1+1+1+1=29

87/29 = 3

molecular formula is (C₂H₅)x 3 = C₆H₁₅

Question 24

What is an empirical formula?

Answer 24

the simplest whole number ration of atoms in a substance

Question 25

Below is an example calculation to find mass of a substance produced in a reaction.

List the steps you take to complete this calculation

Answer 25

Question 26

The apparatus below is used to find the empirical formula of magnesium oxide.

2Mg + O₂ –> 2MgO

1. Measure the mass of the crucible + lid
2. Add a coiled piece of magnesium metal
3. Measure the mass of the crucible + lid + magnesium metal
4. Heat the crucible using a roaring flame - be sure to lift the lid every minute
5. When all the magnesium turns white, turn off the Bunsen burner and allow it to cool
6. Measure the mass of the crucible + lid + Magnesium oxide.
7. Repeat the heating and measuring the mass when cool until constant mass is reached.

Why is the magnesium coiled?

Answer 26

The magnesium is loosely coiled to give the magnesium a large surface area and ensure all the magnesium reacts with the oxygen.

Question 27

The apparatus below is used to find the empirical formula of magnesium oxide.

2Mg + O₂ –> 2MgO

1. Measure the mass of the crucible + lid
2. Add a coiled piece of magnesium metal
3. Measure the mass of the crucible + lid + magnesium metal
4. Heat the crucible using a roaring flame - be sure to lift the lid every minute and replace it
5. When all the magnesium turns white, turn off the Bunsen burner and allow it to cool
6. Measure the mass of the crucible + lid + Magnesium oxide.
7. Repeat the heating and measuring the mass when cool until constant mass is reached.

What are the possible inaccuracies in this method?

Answer 27

1. The magnesium ribbon is impure magnesium
2. The magnesium ribbon has an oxide layer at the start
3. The magnesium ribbon has not fully reacted- some magnesium at the centre of the ribbon is not exposed to oxygen, lid not lifted enough
4. Experiment was not repeated until constant mass was achieved.

Question 28

If 0.2 moles of methane reacted with excess chlorine, how many moles of hydrogen chloride would be produced?

Answer 28

1 : 4 mole ratio

0.2 x 4 = 0.8 moles of hydrogen chloride would be produced.

Question 29

How do you find the empirical formula of a substance if you were given the percentage by mass of atoms in the substance?

Answer 29

1. Assume 100g of substance
2. Calculate the moles of each element
3. Divide by the smallest to get the ratio
4. Multiply up to get whole number

Question 30

How many moles of H₂O would be produced if 0.25 mol of O₂ was reacted with excess hydrogen?

Answer 30

1 : 2 mole ratio

0.25 x 2 = 0.5 mol

Therefore 0.5 mol of H₂O would be produced

Question 31

How many molecules are there in 2 moles of oxygen?

Answer 31

2 x 6.03 x 10²³ molecules

OR 12.6 x 10²³ molecules

Question 32

Show that the RAM of chlorine is 35.5, if a sample of chlorine contains 75% Cl-35 and 25% Cl-37.

Answer 32

[0.75 x 35] + [0.25 x 37] = 26.25 + 9.25 = 35.5

Question 33

The apparatus below is used to find the empirical formula of magnesium oxide.

2Mg + O₂ –> 2MgO

1. Measure the mass of the crucible + lid
2. Add a coiled piece of magnesium metal
3. Measure the mass of the crucible + lid + magnesium metal
4. Heat the crucible using a roaring flame - be sure to lift the lid every minute
5. When all the magnesium turns white, turn off the Bunsen burner and allow it to cool
6. Measure the mass of the crucible + lid + Magnesium oxide.
7. Repeat the heating and measuring the mass when cool until constant mass is reached.

Why is the lid lifted every minute during the heating process?

Answer 33

To allow oxygen in to react with the magnesium- this ensures that all the magnesium has reacted.

Question 34

4.4 moles of iron are reacted with excess oxygen. How many moles of iron oxide are made?

Answer 34

Mole ration of Fe to Fe₂O₃ is 4 : 2 or 2 : 1

4.4 /2 = 2.2 moles of Fe₂O₃ are made

Question 35

What is the mass of 2 moles of carbon?

Answer 35

2 x 12 g/mol = 24 g

Question 36

What is a molecular formula?

Answer 36

The number of atoms in a substance

Question 37

How many moles of H₂O would be produced if 0.5 mol of H₂ was reacted with excess oxygen?

Answer 37

2:2 mole ratio

Therefore 0.5 mol of H₂O would be produced

Question 38

The apparatus below is used to find the empirical formula of magnesium oxide.

2Mg + O₂ –> 2MgO

1. Measure the mass of the crucible + lid
2. Add a coiled piece of magnesium metal
3. Measure the mass of the crucible + lid + magnesium metal
4. Heat the crucible using a roaring flame - be sure to lift the lid every minute and replace it
5. When all the magnesium turns white, turn off the Bunsen burner and allow it to cool
6. Measure the mass of the crucible + lid + Magnesium oxide.
7. Repeat the heating and measuring the mass when cool until constant mass is reached.

Why is the lid replaced after lifting each time?

Answer 38

To ensure that no product is lost

Question 39

If 4.2 moles of methane reacted with excess chlorine, how many moles of tetrachloro methane would be produced?

Answer 39

1 : 1

4.2 moles of tetrachloromethane would be produced

Question 40

What does the empirical formula MgO tell you about the compound?

Answer 40

MgO

There is 1 atom of Mg for every 1 atom of oxygen

In MgO there are 1 mole of Mg atoms for every 1 mole of O atoms.

Question 41

What is the mole ratio of O₂ to H₂O

Answer 41

1 : 2 mole ratio

Question 42

How many atoms are there in a mole of substance?

Answer 42

6.02 x 10²³ atoms

This is called Avogadro’s number