Alcohols and Haloalkanes

Question 1

What is the general formula of an alcohol?

Answer 1

Cn H2n+1 OH

Question 2

What is the suffix of an alcohol with 2 hydroxyl (OH) groups?

Answer 2

-diol

Question 3

What is a primary alcohol?

Answer 3

An alcohol where the -OH group is attached to a carbon with 1 alkyl group attached

Question 4

What is a secondary alcohol?

Answer 4

An alcohol where the -OH group is attached to a carbon with 2 alkyl groups attached

Question 5

What is a tertiary alcohol?

Answer 5

An alcohol where the -OH group is attached to a carbon with 3 alkyl groups attached

Question 6

What is an alkyl group?

Answer 6

An alkane with a Hydrogen removed e.g CH3

Question 7

What is electronegativity?

Answer 7

The ability of an atom to attract the bonding electrons in a covalent bond

Question 8

Why are alcohols classed as polar molecules?

Answer 8

Because the electronegative hydroxyl groups pulls the electrons in the C-OH bond away from the carbon atom, forming a dipole

Question 9

What dipoles are there in an O-H bond?

Answer 9

ẟ- O-H ẟ+

Question 10

In an alcohol, what does the partial positive charge on the Hydrogen atom in the hydroxyl group cause?

Answer 10

It attracts the lone pairs on an oxygen from a neighbouring molecule, forming a Hydrogen bond

Question 11

What happens, in terms of bonds, when you mix an alcohol with water?

Answer 11

Hydrogen bonds form between the -OH group and the H2O

Question 12

What is the trend in solubility of alcohols as they increase in size?

Answer 12

As alcohols increase in size, they become less soluble in water

Question 13

Why do alcohols become less soluble in water as they increase in size?

Answer 13

Smaller alcohols are more polar, meaning the Hydrogen bonding lets it mix freely with water. In larger alcohols, most of the molecule is a non-polar carbon chain, so there’s less attraction for the polar H2O molecules

Question 14

Describe the volatility of alcohols

Answer 14

They have a low volatility

Question 15

Why do alcohols have a low volatility?

Answer 15

Because they can form Hydrogen bonds (strongest type of intermolecular force) meaning it takes more energy to evaporate to a gas

Question 16

What can be said about the boiling point of alcohols?

Answer 16

They have a relatively high boiling point

Question 17

Why do alcohols have a relatively high boiling point?

Answer 17

Because they can form Hydrogen bonds (strongest type of intermolecular force) meaning it takes more energy to break the intermolecular bonds

Question 18

What is the name of the reaction when an alcohol reacts with compounds containing Halide ions?

Answer 18

Substitution reaction

Question 19

What does an alcohol turn into when undergoing a substitution reaction?

Answer 19

A Haloalkane, as the -OH group is replaced by the halide

Question 20

What catalyst is used in an alcohol substitution reaction?

Answer 20

An acid catalyst, such as H2SO4 (sulfuric acid)

Question 21

How do you make an alkene from an alcohol?

Answer 21

You can do an elimination reaction, which eliminates the water from the alcohol

Question 22

What is a substitution reaction?

Answer 22

A reaction where some atoms from one reactant are swapped with atoms from another reactant

Question 23

What is an elimination reaction?

Answer 23

A reaction in which a pair of atoms or group of atoms are removed from an organic compound

Question 24

What 2 possible catalysts are used for the elimination reaction of alcohols?

Answer 24

Concentrated H2SO4 (sulfuric acid)
Concentrated H3PO4 (phosphoric acid)

Question 25

How do alcohols undergo an elimination reaction?

Answer 25

They are heated in the presence of a catalyst

Question 26

What is the water molecule that is eliminated from an alcohol when making an alkene made up of?

Answer 26

A hydroxyl group and a hydrogen atom that was bonded to a carbon atom adjacent to the hydroxyl carbon

Question 27

What are the products for the combustion of alcohols?

Answer 27

Water and carbon dioxide

Question 28

What is the oxidising agent used for the oxidation of alcohols?

Answer 28

Acidified potassium dichromate (VI)

K2Cr2O7 / H2SO4

Question 29

What are the 2 products, in chronological order of formation, for the oxidisation of primary alcohols?

Answer 29

Oxidised to aldehydes and then to carboxylic acid

Question 30

What is the only product of the oxidation of secondary alcohols?

Answer 30

Ketones

Question 31

What is the colour change for the oxidation of primary and secondary alcohols?

Answer 31

Orange —> Green

Question 32

Why is the colour change for the oxidation of primary and secondary alcohols orange to green?

Answer 32

Because the orange dichromate ion is reduced to the green chromium ion, Cr 3+

Question 33

What is the colour change for the oxidation of tertiary alcohols?

Answer 33

No colour change because tertiary alcohols don’t oxidise

Question 34

What is the functional group of carbonyl compounds?

Answer 34

C=O

Question 35

What is the general formula of aldehydes and ketones?

Answer 35

CnH2nO

Question 36

What is the difference between aldehydes and ketones?

Answer 36

Aldehydes have a hydrogen and one alkyl group attached to the carbonyl carbon atom, whereas ketones have 2 alkyl groups, but no hydrogens, attached to the carbonyl carbon atom

Question 37

What is the functional group of an aldehyde?

Answer 37

-CHO

Question 38

What is the suffix for naming aldehydes?

Answer 38

-al (e.g. propanal)

Question 39

Why don’t you have to name which carbon the functional group is on for aldehydes?

Answer 39

It’s always on carbon-1 atom

Question 40

What is the suffix for naming ketones?

Answer 40

-one (e.g. propanone)

Question 41

What is propanone commonly used for?

Answer 41

Nail varnish remover

Question 42

What is the functional group of carboxylic acids?

Answer 42

-COOH

Question 43

What is the suffix for naming carboxylic acids?

Answer 43

-oic (e.g. propanoic acid)

Question 44

Why is the functional group of carboxylic acids not written as CO2H?

Answer 44

Written as COOH to show that the oxygens are different (one is part of carbonyl group and other is part of OH group)

Question 45

What is a primary alcohol first oxidised into?

Answer 45

An aldehyde

Question 46

What can an aldehyde, formed from the oxidation of a primary alcohol, be oxidised into?

Answer 46

A carboxylic acid

Question 47

What is the notation used to represent an oxidising agent?

Answer 47

[O]

Question 48

What conditions are needed to form an aldehyde from a primary alcohol?

Answer 48

Distillation

Question 49

How do you form just the aldehyde from a primary alcohol?

Answer 49

By removing it from the oxidising agent as soon as it’s formed, otherwise it’ll oxidise further to form a carboxylic acid

Question 50

Why do you use distillation apparatus to form an aldehyde from a primary alcohol?

Answer 50

Because it distils the aldehyde as soon as it forms, thus removing it from the oxidising agent

Question 51

What does heating the primary alcohol using reflux mean for the products produced?

Answer 51

You still make an aldehyde first, but because it stays in the reaction vessel with the oxidising agent, it oxidises further to form a carboxylic acid

Question 52

What is the balanced equation for the oxidation of a ethanol using distillation?

Answer 52

ethanol + [O] —> ethanal + water

Question 53

What is the balanced equation for the oxidation of a ethanol using reflux?

Answer 53

ethanol + 2[O] —> ethanoic acid + water

Question 54

What does heating under reflux mean?

Answer 54

Means you can increase the temperature of an organic reaction to boiling without losing volatile solvents, reactants or products

Question 55

To form a carboxylic acid, what does a primary alcohol have to be heated under reflux with?

Answer 55

An excess amount of oxidising agent so that it is vigorously oxidised

Question 56

How does heating under reflux mean that no volatile solvents, reactants or products are lost?

Answer 56

Because any vaporised compounds are cooled as they rise, so then condense and drip back into the reaction mixture

Question 57

What does refluxing a secondary alcohol with an oxidising agent form?

Answer 57

A ketone

Question 58

What is the balanced equation for the oxidation of propan-2-ol?

Answer 58

propan-2-ol + [O] —> propanone + water

Question 59

Why is a ketone the only product of oxidising secondary alcohols?

Answer 59

Because ketones can’t be oxidised easily any further

Question 60

How can you do a test to find out if an alcohol is tertiary or not?

Answer 60

If you heat the alcohol with acidified potassium dichromate, the solution will not change colour if it is a tertiary alcohol, because they can’t be oxidised. If it is a primary or secondary alcohol, the solution will turn green, as it can be oxidised

Question 61

What is a haloalkane?

Answer 61

An alkane with at least one halogen replacing a hydrogen

Question 62

If a haloalkane contains both bromine (bromo- suffix) and iodine (iodo- suffix), which do you write first when naming the haloalkane?

Answer 62

Bromo- because it’s before iodo- in the alphabet

Question 63

Is the carbon-halogen bond in haloalkanes polar or non-polar?

Answer 63

Polar

Question 64

Why is the carbon-halogen bond in haloalkanes polar?

Answer 64

Halogens are more electronegative than carbon, causing the electrons to be attracted to the halogen

Question 65

Draw the dipoles of the carbon-halogen bond in haloalkanes

Answer 65

ẟ+ C-Br ẟ- (carbon has a positive charge because electrons shift towards the halogen)

Question 66

What happens in a nucleophilic substitution reaction?

Answer 66

The lone pair of electrons on the nucleophile attacks a the slight positive charge on the carbon to create a new bond

Question 67

What is the equation for the nucleophilic substitution of Halogen X?

Answer 67

RX + Nu- —> RNu + X-

where Nu is the nucleophile and R is the alkyl group

Question 68

What is nucleophilic substitution?

Answer 68

Where a nucleophile attacks a polar molecule and replaces the functional group

Question 69

What type of fission is the bond breaking between the carbon and the halogen in nucleophilic substitution?

Answer 69

Heterolytic - as both of the bonding electrons are taken by the halogen

Question 70

What is a hydrolysis reaction?

Answer 70

A reaction where molecules are split up by water (which also split up into H+ and OH-)

Question 71

What is the product of the hydrolysis of a haloalkane?

Answer 71

Alcohols

Question 72

What are the 2 ways of doing hydrolysis of haloalkanes to make alcohols?

Answer 72

Hydrolysis with aqueous alkali

Hydrolysis with water

Question 73

Give 2 examples of alkalis that could be used for the hydrolysis of haloalkanes?

Answer 73

Sodium hydroxide (NaOH)
Potassium hydroxide (KOH)

Question 74

What is the general equation for the hydrolysis of haloalkanes with aqueous alkali?

Answer 74

RX + -OH —> ROH + X-

Question 75

Compare the speed of hydrolysis using water and using aqueous alkali

Answer 75

Using water is much slower because water is a weak nucelophile

Question 76

What is the general equation for the hydrolysis of a haloalkane using water?

Answer 76

RX + H2O —> ROH + H+ X-

Question 77

What happens with hydrolysis if you’ve got more than one halogen present in the molecule?

Answer 77

The halogen with the lowest bond enthalpy will be replaced first

Question 78

How does the speed of when haloalkanes are hydrolysed depend on?

Answer 78

The bond enthalpy of the carbon-halogen bond

Question 79

Which does faster hydrolysis, fluoroalkanes or iodoalkanes?

Answer 79

Iodoalkanes because the C-I bonds have a lower bond enthalpy than the C-F bonds

Question 80

When doing the practical to compare hydrolysis rates of haloalkanes, why do you use water as the nucleophile instead of an alkali?

Answer 80

If you used the alkali the hydroxide ions would react with the silver nitrate to form a precipitate and mess up the results

Question 81

What does CFC stand for?

Answer 81

Chlorofluorocarbons

Question 82

Describe the stability of CFCs

Answer 82

Very stable because they contain no hydrogens

Question 83

What are CFCs?

Answer 83

Fully halogenated paraffin hydrocarbons that contain only carbon, chlorine, and fluorine

Question 84

Describe the volatility of CFCs

Answer 84

Volatile

Question 85

Describe the flammability and toxicity of CFCs

Answer 85

Non-flammable and non-toxic

Question 86

Where is the ozone layer?

Answer 86

A layer that is in a layer of the atmosphere called the stratosphere

Question 87

What is the molecular formula for ozone?

Answer 87

O3

Question 88

How does the ozone layer benefit humans?

Answer 88

It absorbs UV radiation from space, meaning it decreases the chance of sunburn or skin cancer

Question 89

How does ozone form?

Answer 89

When an oxygen atom is broken down into 2 free radicals by UV radiation

Question 90

What is the chemical mechanism for the formation of ozone?

Answer 90

O2 + UV —> O + O

O2 + O —> O3

Question 91

How are holes forming in the ozone layer?

Answer 91

The CFCs that are travelling up into the atmosphere absorb UV radiation and split up into 2 chlorine radicals. These radicals then destroy ozone molecules and then are regenerated to destroy more ozone

Question 92

Write the mechanism for the destruction of the ozone layer

Answer 92

CF2Cl2 + UV —> CF2Cl• + Cl•
Cl• + O3 —> O2 + ClO•
ClO• + O —> O2 + Cl•

Question 93

On average, how many ozone molecules can a singular chlorine atom destroy before becoming stable?

Answer 93

10,000

Question 94

What is the general equation for the destruction of ozone?

Answer 94

O3(g) + O(g) —> 2O2(g) … where Cl• is a catalyst

Question 95

What type of catalyst is the Cl• in the destruction of ozone?

Answer 95

Homogenous catalyst, because it’s in the same phase (state) as the ozone molecules

Question 96

What is the problem with CFCs being so stable?

Answer 96

They don’t get broken down in the lower atmosphere, so they can travel further up to the ozone layer where they destroy it

Question 97

What is another example of free radicals that destroy the ozone layer, apart from Cl•?

Answer 97

NO• from nitrogen oxides

Question 98

Gives 3 examples of where nitrogen oxides are produced from

Answer 98

Planes
Cars
Thunderstorms

Question 99

How do thunderstorms release nitrogen oxides?

Answer 99

Each bolt of lightning carries electrical energy that is powerful enough to break the strong bonds of the nitrogen molecule in the atmosphere. Once split, the nitrogen atoms quickly bond to oxygen in the atmosphere, forming nitrogen dioxide

Question 100

Why were CFCs banned?

Answer 100

Because scientific evidence showed that the advantages of using CFCs couldn’t outweigh the environmental damage they were causing

Question 101

What was the Montreal Protocol 1987?

Answer 101

An international treaty to phase out the use of CFCs and other ozone-damaging haloalkanes by the year 2000

Question 102

What does HCFCs stand for?

Answer 102

Hydrochlorofluorocarbons

Question 103

What does HFCs stand for?

Answer 103

Hydrofluorocarbons

Question 104

What 2 haloalkanes are being used instead of CFCs?

Answer 104

HCFCs

HFCs

Question 105

Compare, on average, how long it takes CFCs to leave the atmosphere compared to HCFCs

Answer 105

CFCs take around 90 years whereas HCFCs take between 10-20 years

Question 106

Do HCFCs damage the ozone layer?

Answer 106

Yes, but the effect is much less than CFCs

Question 107

Do HFCs damage the ozone layer?

Answer 107

No because they don’t contain chlorine

Question 108

What are HCFCs and HFCs examples of?

Answer 108

Greenhouse gases

Question 109

What were CFCs originally used a lot in, until they were banned?

Answer 109

Fridges, Aerosols, Air-conditioning

Question 110

What is the troposphere?

Answer 110

The lowest level of the atmosphere

Question 111

What is the greenhouse effect?

Answer 111

The absorption and re-emission of infrared radiation by greenhouse gases in the troposphere

Question 112

What happens when EM radiation reaches Earth?

Answer 112

It is absorbed then re-emitted as infrared radiation (heat)

Question 113

What happens to the infrared radiation once the Earth has re-emitted it?

Answer 113

The gases in the troposphere absorbs it and then re-emits it in all direction, including back towards Earth

Question 114

What are the 3 main greenhouse gases?

Answer 114

Methane
Carbon dioxide
Water vapour

Question 115

What is a greenhouse gas?

Answer 115

A gas that absorbs and re-emits infrared radiation, thus contributing to the greenhouse effect

Question 116

What happens to the bonds of the greenhouse gases when they absorb infrared radiation?

Answer 116

The bonds in the molecule vibrate more, this extra energy is passed on to other molecules in the air by collisions, giving them more kinetic energy and raising the temperature

Question 117

What are the 3 factors that the contribution to the greenhouse effect depends on?

Answer 117

How much IR radiation one molecule of the gas absorbs
How much of that gas there is in the atmosphere
How long the gas stays in the atmosphere for

Question 118

What is global warming?

Answer 118

The warming of the planet due to increased concentrations of greenhouse gases in the troposphere, which enhance the greenhouse effect

Question 119

Why does the concentration of water vapour in the atmosphere stay roughly the same?

Answer 119

Because if there’s too much it falls to Earth as rain

Question 120

What does anthropogenic mean?

Answer 120

Human impact on the environment

Question 121

What are 3 environmental problems to do with global warming?

Answer 121

Ice caps will melt leading to a rise in sea levels
Stormier, less predictable weather
Less rainfall in some areas, leading to drought

Question 122

What is the Kyoto Protocol of 1997?

Answer 122

Where industrialised countries, such as UK, promised to reduce greenhouse gas emissions to agreed levels

Question 123

When did the Kyoto Protocol come to an end?

Answer 123

2012

Question 124

How are governments working to reduce the amount of greenhouse gases going into the atmosphere?

Answer 124

Using more renewable energy resources, such as wind turbines and solar farms