OZ - Haloalkanes and ozone

Question 1

How many types of bond fission are there?

Answer 1

2

Question 2

What are the 2 types of bond fission?

Answer 2

Homolytic and heterolytic.

Question 3

What is bond fission?

Answer 3

Breaking a covalent bond.

Question 4

What is breaking a covalent bond called?

Answer 4

Bond fission.

Question 5

What is a single covalent bond?

Answer 5

A shared pair of electrons between two atoms.

Question 6

What is a shared pair of electrons between two atoms?

Answer 6

A single covalent bond.

Question 7

In what two ways can a single covalent bond break?

Answer 7

Heterolytic fission and homolytic fission.

Question 8

What is heterolytic fission?

Answer 8

When two different substances are formed - a positively charged cation (X+), and a negatively charged anion (X-).

Question 9

What does ‘hetero’ mean?

Answer 9

‘Different’.

Question 10

What is homolytic fission?

Answer 10

Two electrically uncharged ‘radicals’ are formed. Radicals are particles that have an unpaired electron. Because of the unpaired electron, these radicals are very reactive.

Question 11

What are radicals?

Answer 11

Particles that have an unpaired electron.

Question 12

Are radicals very reactive or not?

Answer 12

They are very reactive.

Question 13

Why are radicals very reactive?

Answer 13

Because of the unpaired electron they have.

Question 14

What does a double-headed arrow show?

Answer 14

That a pair of electrons move.

Question 15

What does a single-headed arrow show?

Answer 15

The movement of a single electron.

Question 16

What do radicals take part in?

Answer 16

Chain reactions.

Question 17

When do chain reactions take place?

Answer 17

If a product causes more reactions to take place.

Question 18

How many main stages do radical chain reactions have?

Answer 18

3

Question 19

What are the 3 main stages of radical reactions?

Answer 19

Initiation reactions.
Propagation reactions.
Termination reactions.

Question 20

What happens in initiation reactions?

Answer 20

Free radicals are produced.

Question 21

What happens in propagation reactions?

Answer 21

Free radicals react with molecules and produce new radicals. These go on to react with more molecules, producing even more radicals. This is the chain part of the reaction.

Question 22

What happens in termination reactions?

Answer 22

Two radicals react together to form a stable molecule.

Question 23

In what stage of a radical chain reaction are free radicals are produced?

Answer 23

Initiation reactions.

Question 24

In what stage of a radical chain reaction do free radicals react with molecules and produce new radicals. These go on to react with more molecules, producing even more radicals. This is the chain part of the reaction?

Answer 24

Propagation reactions.

Question 25

In what stage of a radical chain reaction do two radicals react together to form a stable molecule?

Answer 25

Termination reactions.

Question 26

What can halogen radicals react with and what does this form?

Answer 26

Alkanes to form haloalkanes.

Question 27

In what reactions do halogens react with alkanes?

Answer 27

Photochemical reactions.

Question 28

What are photochemical reactions started by?

Answer 28

Light.

Question 29

What happens in the photochemical reaction between a halogen and an alkane?

Answer 29

A hydrogen atom is substituted (replaced) by chlorine or bromine. This is a radical chain reaction.

Question 30

Apart from a photochemical reaction, what type of reaction is the reaction between a halogen and an alkane?

Answer 30

A radical chain reaction.

Question 31

Describe the three stages of the radical chain reaction between chlorine and methane to form chloromethane

Answer 31

Initiation reaction:

• Sunlight provides enough energy to break the Cl-Cl bond - this is photodissociation.
• The bond splits equally and each atom gets to keep one electron - homolytic fission.
• The molecule forms two highly reactive free chlorine radicals.

Propagation:

• The chlorine radical attacks a methane molecule, forming a hydrogen halide and a methyl radical.
• The new methyl free radical can attack another chlorine (Cl2) molecule.
• The new chlorine radical can attack another methane molecule, and so on, until all the chlorine or methane molecules are wiped out.

Termination:

• If two free radicals join together, they make a stable molecule.
• There are heaps of possible termination reactions.

Question 32

What is photodissociation?

Answer 32

When sunlight provides enough energy to break bonds between/in molecules.

Question 33

What will some of the products be in a termination reaction of a radical chain reaction?

Answer 33

Trace impurities in the final sample.

Question 34

What is the ozone layer?

Answer 34

A ‘layer’ in the stratosphere containing most of the atmosphere’s ozone molecules (O3).

Question 35

Where is the ozone layer?

Answer 35

In the layer of the atmosphere called the stratosphere.

Question 36

When is ozone formed?

Answer 36

When UV radiation from the sun hits oxygen molecules.

Question 37

Explain how ozone molecules are formed by oxygen and UV radiation from the sun:

Answer 37

If the right amount of UV radiation is absorbed by an oxygen molecule, the oxygen molecule splits into separate atoms or free radicals.

The free radicals then combine with other oxygen molecules to form ozone molecules, O3.

Question 38

What does ‘hv’ stand for in the formation of ozone?

Answer 38

A quantum of UV radiation.

Question 39

Why is the ozone layer important to us?

Answer 39

Because it protects us from most of the harmful effects of the Sun’s ultraviolet (UV) radiation.

Question 40

What happens to ozone when it breaks down that is so dangerous to most life on Earth?

Answer 40

When ozone breaks down, it absorbs high energy UV radiation, so the ozone layer removes all the high energy UVC radiation and about 90% of the UVB. These types of UV radiation are harmful to humans and most other life on Earth.

Question 41

What is UV radiation from the sun made up of?

Answer 41

Different frequencies, grouped into three bands: UVA, UVB and UVC (increasing in frequency and energy).

Question 42

Why is UVB bad?

Answer 42

Because it can damage the DNA in cells and cause skin cancer and is the main cause of sunburn. It also causes the skin to age faster.

Question 43

Why is UVA bad?

Answer 43

Can lead to skin cancer and causes the skin to age faster.

Question 44

Are UVA and UVB bad or good?

Answer 44

Mainly bad.

Question 45

It UV radiation good or bad?

Answer 45

Both.

Question 46

Why is UV radiation good?

Answer 46

It is essential for humans as wee need it to produce vitamin D. Also, it causes the skin to tan when the skin is exposed to UV which helps protect deeper tissues from the effects of the radiation.

Question 47

Why does ozone occur at ground level?

Answer 47

Occurs in the troposphere (the lowest part of the atmosphere) due to the effect of sunlight on mixture of nitrogen dioxide and hydrocarbons (which occur naturally from a variety of sources but vehicle engines and power stations contribute large amounts).

Question 48

What is ‘ground level’/the lowest part of the atmosphere called scientifically?

Answer 48

The troposphere.

Question 49

Why are there large amount of nitrogen dioxide and hydrocarbons in the troposphere?

Answer 49

They occur naturally from a variety of sources but vehicle engines and power stations contribute large amounts.

Question 50

What can happen to ozone in the troposphere in industrialised areas and cities with lots of cars?

Answer 50

The ozone mixes with solid particles of carbon and many other substances to create an air pollutant called photochemical smog.

Question 51

What problems are there around photochemical smog?

Answer 51

It can cause respiratory problems.
It can be dangerous for animals.
It can cause damage to plants and materials.
Ozone itself is toxic to humans.

Question 52

How does photochemical smog form?

Answer 52

In the troposphere in industrialised areas and cities with lots of cars, the ozone mixes with solid particles of carbon and many other substances to create an air pollutant called photochemical smog.

Question 53

What do CFCs do?

Answer 53

Break down ozone in the stratosphere.

Question 54

What breaks down ozone in the stratosphere?

Answer 54

CFCs.

Question 55

What are CFCs?

Answer 55

Chlorofluorocarbons are haloalkanes that have all their hydrogen atoms replaced by chlorine and fluorine atoms.

Question 56

Why/how can CFCs break down ozone in the stratosphere?

Answer 56

The C-Cl bond can be broken down by high energy UV radiation in the stratosphere to form chlorine radicals - these act as catalysts on the breakdown of ozone.

Question 57

Why is ozone less likely to be broken down by CFCs in the troposphere?

Answer 57

Because most of the high frequency UV has been absorbed by the ozone layer. Though ozone can still be broken down in the troposphere, it’s much less likely to happen because there are less suitable catalysts.

Question 58

What factor of UV radiation determines whether it can break bonds?

Answer 58

The frequency no the intensity of UV radiation.

Question 59

Why/how can UV radiation break haloalkanes?

Answer 59

All haloalkanes contain bonds between carbon atoms and halogen atoms. UV radiation can break these bonds - the carbon-halogen bond splits homolytically to create two free radicals.

The ease with which the carbon-halogen bond it broken by UV depends on the halogen. It turns out that the carbon-iodine bond is the most likely to break, and the carbon-fluorine bond the least likely. This is because the C-I bond has the lowest bond enthalpy, and the C-F bond the highest.

Question 60

How does the ease with which UV can break carbon-halogen bonds change with different halogens?

Answer 60

The ease with which the carbon-halogen bond it broken by UV depends on the halogen. It turns out that the carbon-iodine bond is the most likely to break, and the carbon-fluorine bond the least likely. This is because the C-I bond has the lowest bond enthalpy, and the C-F bond the highest.

Question 61

By what process is the ozone layer being destroyed?

Answer 61

Homogenous catalysis.

Question 62

Explain what is happening when the ozone layer is being destroyed by CFCs/homogenous catalysis

Answer 62

• Chlorine free radicals, Cl. , are formed when CFCs are broken down by high energy UV radiation in the stratosphere.
• These free radicals are catalysts. They react with ozone to form an intermediate (ClO.), and an oxygen molecule.
• The reaction can only terminate if two radicals react together (e.g. Cl. (g) + Cl. (g) –> Cl2 (g))
• So the overall reaction is 2O3(g) –> 3O2(g) and Cl. is the catalyst.

Question 63

Other than free chlorine radicals, what other free radicals can destroy ozone?

Answer 63

NO from nitrogen oxides,
e.g. NO2 (g) + hv –> NO. (g) + O (g)

Other halogen free radicals from haloalkanes.

Question 64

How can the overall reactions between free radicals and ozone be represented?

Answer 64

R + O3 –> RO + O2
O + RO –> O2 +R

Where R represented the free radical.