C3: Chemical Economics

Question 1

What is the formula of magnesium sulfate?

Answer 1

MgSO4

Question 2

Which two factors can determine the rate of reaction?

Answer 2

1. The collision frequency of reacting particles

2. The energy transferred in each of the collisions (i.e. whether each collision is successful)

Question 3

In terms of the reacting particle model, why does increasing the temperature increase the rate of reaction?

Answer 3

1. At a higher temperature the particles are vibrating and moving more quickly. As a result, it is more likely that they will collide.
2. Furthermore, the increased temperature mean that the particles are moving with a greater amount of energy. Therefore, particles will be colliding with greater energy, meaning there will be more successful collisions per second.

Question 4

In terms of the reacting particle model, why do increases in concentration cause an increase in the rate of reaction?

Answer 4

1. If the concentration is increased, there will be more particles of the reactant in the same volume of solution
2. Therefore, it is more likely particles will successfully collide with each other each second.

Question 5

In terms of the reacting particle model, why do increases in pressure result in an increase in the rate of reaction?

Answer 5

1. If the pressure is greater, the particles are more crowded and closer together
2. As a result, they are more likely to collide with each other.

Question 6

What is a catalyst?

Answer 6

A substance that increases the rate of reaction without being chemically changed in the reaction. There are specific catalysts for specific reactions, and are usually only needed in small quantities.

Question 7

Why do catalysts increase the rate of reaction?

Answer 7

1. They provide a surface for the reacting particles to stick to
2. This reduces the energy needed by particles to react
3. As a result, the number of successful collisions increases

Question 8

Why do powdered substances react faster than large solids and lumps?

Answer 8

1. Chemicals made up of smaller pieces (powders) have a greater total surface area
2. As a result, particles have a greater area to collide with
3. Therefore, there will be more successful collisions every second
4. So rate of reaction increases

Question 9

Why are fine powders of combustible material dangerous to handle in factories?

Answer 9

• Fine powders have a very large surface area, so they combust extremely quickly
• As a result a single spark can cause a huge explosion
• Factories need to be very careful when handling custard powder, flour and powdered sulfur

Question 10

What is meant by the principles of the conservation of mass?

Answer 10

The total mass of the reactants at the start of the reaction is equal to the total amount of product made at the end of the reaction.

Question 11

What is percentage yield?

Answer 11

The amount of product made (actual yield) compared to the amount of scientifically predicted product made (predicted yield). Percentage yield = actual yield (grams)/predicted yield (grams)*100

Question 12

Why is percentage yield usually less than 100%?

Answer 12

• Loss in filtration
• Loss in evaporation
• Loss in transferring liquids
• Not all reactants react to make product (other/different/unintended reactions happening)

Question 13

What is atom economy?

Answer 13

The amount of desired product produced compared to the total amount of product produced.
atom economy= total Mr of desired products/total Mr of all products * 100

Question 14

Why do manufacturers want high percentage yields?

Answer 14

• To reduce wastage of reactants

- To reduce costs (and increase profits)

Question 15

Why do manufacturers want a high atom economy?

Answer 15

• To reduce the production of unwanted products, therefore reducing the amount of waste materials that need to be disposed.
• By reducing wastage, the process becomes more sustainable

Question 16

Describe a simple calorimetric method for comparing the energy transferred in combustion reactions.

Answer 16

1. Spirit burner or bottle gas burner used
2. Water heated in copper calorimeter
3. Fuel is weighed before and after. Mass of fuel burned recorded
4. Temperature change recorded
5. Fair and valid test carried out

Question 17

How can the purity of drugs be tested?

Answer 17

• Pure substances won’t be separated by chromatography - it will all move as one blob
• Pure substances will have a specific melting and boiling point. Therefore, if the substance is impure, it will have a lower melting point and a boiling point higher than expected

Question 18

Explain why batch processes are used to make pharmaceutical drugs but continue as processes are used to produce chemicals such as ammonia.

Answer 18

Pharmaceutical drugs:

• Involved skilled labour intensive work which can’t be automated
• Low demand, so less needed

Ammonia:

• product needed all year round
• it can be automated as not very labour intensive

Question 19

Describe the advantages and disadvantages of batch and continuous manufacturing.

Answer 19

Batch:

• Flexible (different products can be made using same equipment)
• Start up costs are relatively low
• It is labour intensive; equipment needs to be manually controlled
• It can be tricky to produce the exact same product over and over again

Continous:

• Production never stops; time not wasted restarting react
• It runs automatically; lower labour costs

Question 20

Why is it expensive to make and produce drugs?

Answer 20

• Huge research and development costs; highly paid scientist need to find chemical compound
• Trialling; lengthy human and animal trials need to be carried out. Legal requirements need to be met
• Manufacturing by batch is labour intensive and can’t be automated
• Raw materials from plants can sometimes be expensive

Question 21

Explain why it is difficult to test and develop new pharmaceutical drugs that are safe to use.

Answer 21

1. Strict legal requirements need to be made
2. Lengthy animal and human trials need to be conducted; extremely expensive
3. If drug has unwanted side affects, whole investment may have been wasted
4. Many years of testing needed to check for long term impacts

Question 22

Describe how chemicals are extracted from plant sources.

Answer 22

1. Plant material is crushed
2. Next, it is boiled and dissolved in a suitable solvent
3. Chromatography strip is used to separate the different chemicals.

Question 23

Why are diamond, graphite and fullerenes all allotropes of carbon?

Answer 23

They are just different structural forms of carbon

Question 24

Why is diamond used in cutting tools and jewellery?

Answer 24

• In a diamond, each carbon atom is bonded with 4 other carbon atoms in a giant covalent structure.
• This rigid covalent structure is what makes the diamond extremely hard
• The strong covalent bonds take a lot of energy to break, giving diamond a very high melting point.
• This is also why it is useful as a cutting tool
• Diamonds are lustrous and colourless

Question 25

Why don’t diamonds conduct electricity?

Answer 25

It has no free (delocalised) electrons.

Question 26

Why is graphite used in pencil leads and lubricants

Answer 26

1. Each carbon atom only forms 3 covalent bonds, creating sheets/layers of carbon atoms that can slide over each other
   2 There are weak intermolecular forces between these layers meaning they can be rubbed off onto the paper to leave a black mark
2. The slipperiness of graphite makes it great to use as a lubricant

Question 27

Why does graphite have a high melting point?

Answer 27

Graphite contains lots of strong covalent bonds. Lots of energy is needed to break these bonds meaning that it has a high melting point.

Question 28

Why does graphite conduct electricity?

Answer 28

Each carbon atom only forms 3 covalent bonds, leaving each atom with a spare electron - together, they form a sea of delocalised electrons. This is why graphite is a good electrical conductor.

Question 29

Explain why diamond and graphite have a giant molecular structure?

Answer 29

Carbon atoms are joined in lattices via covalent bonding. They are described as giant due to the large number of covalent bonds involved.

Question 30

Why can fullerenes be used in drug delivery systems?

Answer 30

1. Their structure forms around another atom or molecule
2. This molecule is trapped inside the fullerene
3. This is ideal for a slow release of the drug within a body

Question 31

Explain how the structure of nanotubes enable them to be used as catalysts.

Answer 31

Nanotubes have an extremely large surface area, meaning they would be used as a base for catalysts. A catalyst can be painted in a thin layer over the nanotube, providing the catalyst with a huge surface area to catalyse the reactants.

Question 32

What is the formula for sulfuric acid?

Answer 32

H2SO4

Question 33

What is the formula of calcium chloride?

Answer 33

CaCl2

Question 34

What is the formula of magnesium chloride?

Answer 34

MgCl2