Post on 31-Dec-2015
NATIONAL 5 CHEMISTRY
UNIT 2 NATURE’S CHEMISTRY
Contents Homologous series
•Fuelling Scotland’s future
•Alkanes
•Alkenes
•Cycloalkanes
Fuelling Scotland’s Future
•As North Sea gas and oil runs out Scotland will become dependent on imported gas unless new sources can be identified and exploited.•In the second half of the 19th century and the start of the 20th century Scotland had a thriving shale oil industry.• In 1847 the Scottish chemist James Young prepared "lighting oil," lubricating oil and wax from cannel coal and since 1862 from torbanite. In 1850 he patented the process of cracking oil.•Commercial scale shale oil extraction in Scotland started in 1859 by Robert Bell in Broxburn, West Lothian.
• It was not until 1859 that Amercians struck free-flowing oil.
• Oil shale was mined in the Lothian’s until 1962 but the industry died out because it could no longer compete with imported oil.
Crude oil and hydrocarbons
• Crude oil and its improved industrial extraction and processing produces a wide variety of energy-rich compounds called hydrocarbons.
• Crude oil – is a mixture of unprocessed hydrocarbons (of varying size/length)
• Hydrocarbons – are compounds that contain the element carbon and hydrogen.
Crude oil Hydrocarbons
Separated by their d
ifferent
Separated by their d
ifferent
boiling points
boiling points
How does fractional distillation work?
Forces between molecules
Fractional distillation
Combustion
In order to burn fuels require oxygen.Increasing the concentration of O2(g) increases the rate of burning.
The term ‘combustion’ is used to describe the process of burning (reaction with oxygen).
When combustion takes place the fuel reacts with oxygen in the air and energy is given out.
This means that combustion is an exothermic reaction.
HydrocarbonsHydrocarbons• Many of the fuels that we use are fossil
fuels.
• Fossil fuels were formed millions of years ago from material that was once living.
• There are three common fossil fuels - coal, oil and natural gas.
• The chemical compounds which are found in oil and natural gas are called hydrocarbons.
• These compounds are made up using
the elements hydrogen and carbon only.
Combustion of Combustion of HydrocarbonsHydrocarbons
• When hydrocarbons burn in a plentiful supply of oxygen, the products are carbon dioxide and water.
• This is complete combustion and the products will be the same for any hydrocarbon burning in a good supply of oxygen.
hydrocarbon oxygen carbon dioxide water
Products of CombustionProducts of Combustion
A burning hydrocarbon
is placed under the funnel
The first test tube
is surrounded by ice
The second test tube has lime
water
A pump is used to draw the gases through the apparatus
Tests for products
• Carbon dioxide turns limewater milky.
• Water boils at 100oC and freezes at 0oC. (or by using cobalt chloride paper which turns from blue to pink in the presence of water).
• The fact that water (hydrogen oxide) is produced proves that the fuel contains hydrogen. The fact that carbon dioxide is produced proves that the fuel contains carbon.
Quick Quiz
• Burns to release energy.
• Turns limewater cloudy.
• Burning with oxygen.
• A reaction that releases energy.
• 1:4
What is a fuel?
What is the test for carbon dioxide?
What is combustion?
What is an exothermic reaction?
What is the proportion of oxygen to nitrogen in the air?
Starter1. A mixture of ethanol (boiling point
79oC) and water is distilled. Which liquid will boil first?
2. What is a fraction?
3. Which are smaller, molecule in petrol or molecules in paraffin?
4. What is bitumen used for? 5. The hydrocarbon butane has the
molecular formula C4H10. In which fraction will butane be found?
Ethanol
A group of hydrocarbons with similar chemical properties and of a similar size
Paraffin
Roads and roofing
LPG (liquefied petroleum gas)
Aims:• Discuss the pollution problems
caused by the burning of hydrocarbons.
In the presence of oxygen, hydrocarbons burn to produce carbon dioxide and water.
Where does the carbon dioxide and water come from?
2 2CH4 + O2 CO2 + H2O
Carbon Dioxide• Carbon dioxide is a
greenhouse gas. • This means that it lets the
heat from the sun penetrate through to the earth, but doesn’t let it back out.
• The level of CO2 produced every year is increasing.
• Therefore the temperature of the earth is increasing.
• Effect is increased levels of seas/rivers causing flooding.
Carbon Monoxide• Hydrocarbons burned in insufficient
oxygen can produce carbon and carbon monoxide, which is a very poisonous gas.
• Carbon monoxide destroys blood’s ability to carry oxygen.
Sulphur Dioxide• Some fossil fuels contain small traces of
sulphur.• Sulphur dioxide is also a poisonous gas.• Sulphur dioxide can dissolve in rain to
produce acid rain.• Acid rain leads to corrosion of stonework
and metals.• Most SO2 is produced by coal and oil fired
power stations.• Removing sulphur compounds reduces air
pollution.
Nitrogen oxides•In car engines the air (N2 and O2) around the spark plug is provided with enough energy to cause a reaction between nitrogen and oxygen.
•Oxides of nitrogen are produced (NO2 and NO).
•NO2 dissolves in rain to produce nitric acid.
How Do We Overcome Pollution?
• Catalytic converters in car exhausts change harmful gases less harmful gases.
• E.g. CO CO2
NO and NO2 N2
– Catalytic converters contain transition metals (Pd, Rh or Pt on honey combed structures).
• Lean burn engines increase the ratio of air:fuel and so petrol is burned more efficiently. This causes a decrease in CO and unburned hydrocarbons.
• Leaded compounds have been removed from petrol to reduce pollution.
• Low-sulphur petrol produced.
• Sulphur dioxide removed from gases leaving power stations.
• Lime added to lakes to neutralise the effect of acid rain.
Quick Quiz1. Why does the production of carbon dioxide
and water on burning, indicate the presence of carbon and hydrogen in the original fuel?
2. What does ‘incomplete combustion’ mean?
3. Name a poisonous gas which can be produced as a result of incomplete combustion of petrol in a car engine.
4. Describe some of the effects of acid rain.
5. What does a catalytic converter do, and what type of material is it made from?
DistillationDistillation• This process is used to
separate substances due to them having different boiling points.
• E.g. water and alcohol can be separated using this process.
• Alcohol boils off first at 78oC and pure water is left behind.
Products from Crude OilProducts from Crude Oil
• Crude oil (petroleum) is a mixture of hydrocarbons.
• The hydrocarbons are separated into smaller mixtures (fractions) by a technique called fractional distillation.
• The hydrocarbons can be separated into different fractions using this process because they have different boiling points.
Uses and Properties of Uses and Properties of Fractions from Crude OilFractions from Crude Oil
Refinery gas
Gasoline (Petrol)
Kerosine
(Paraffin)
Gas Oils
(Diesel oil)
Residue
Fuel oil for ships / power stations / heating
Lubrication oils and waxes
Bitumen / tar for roads
Fuel gases
Fuel for cars
Aircraft fuel
Fuel for buses/taxis and cars.
Fraction
Chain length (no.of carbon atoms)
Uses Properties
Boiling pt. (oC)
Flammabillity
ViscosityEase of Evaporation
Refinery gas
1-4 Fuel gas <20
Petrol/ Gasoline (Naptha)
5-12Petrol and petrochemicals
20-180
Paraffin/ Kerosene
9-15Heating and fuel for aeroplanes
180-250
Diesel (Gas oil)
15-25Fuel for lorries/trains
250-350
Residue >25Lubricants, waxes, road tar
>350
DEC
REA
SES
INC
REA
SES
DEC
REA
SES
FractionsFractionsAT THE BOTTOM OF THE COLUMN
•Short carbon chains
•Light molecules •Heavy molecules
•Low boiling points •High boiling points
•Gases & very runny liquids •Thick, viscous liquids
•Very volatile •Low volatility
•Highly flammable •Not very flammable
•Light colour •Dark colour
AT THE TOP OF THE COLUMN
•Long carbon chains
Word BankWord Bank• Viscosity describes how well a liquid pours e.g.
treacle is very viscous, it is thick and pours very slowly. Large hydrocarbons are more viscous than small hydrocarbons.
• Flammability is how easily a substance will catch fire. Small hydrocarbons are more flammable than large hydrocarbons.
• Boiling point is a change of state from liquid to gas.
• Fraction is a group of hydrocarbons with boiling points within a given range.
Catalytic CrackingCatalytic CrackingChanging large hydrocarbons into
smaller more useful hydrocarbons.
e.g. C10H22 C8H18 + C2H4
During this type of reaction a smaller alkane (hydrocarbon) is always produced.
Catalyst
CatalystsCatalysts• A catalyst is a substance which:
– Increases rate of reaction– or– Allows a reaction to occur at a lower
temperature
N.B. A catalysts does not get used up during a chemical reaction. Therefore it is never included in a chemical reaction.
North Sea oil – How much left for Scotland/UK?
• Are there alternatives? And what are the pros and cons? Remember to analyse where your source information comes from [is it without bias?]
http://www.bbc.co.uk/news/uk-14432401
What is Fracking and why is it controversial?
Fracking in the news!
Alternatives in the news
•HydrocarbonHydrocarbon• familiesfamilies
Aims:
Discuss the Alkanes, which are a family of hydrocarbons.
The name for the first eight alkanes.
The structural formula of the first eight alkanes.
The molecular formula of the first eight alkanes.
The general formula for the alkane family.
HydrocarbonsHydrocarbons
• There are 3 hydrocarbon sub-groups:– Alkanes– Alkenes– Cycloalkanes
Same second name
Homologous series
Look similar
AlkanesAlkanes• Homologous series• Look similar• Contain covalent bonds.• All alkanes end in ‘ane’.• Remember each carbon must form 4
bonds. Each hydrogen must form 1 bond only.
Methane CH4
C H
H
H
H
C
H
CH
H
H
H
H
Ethane C2H6
Propane C3H8
C
H
CH
H
H
H
C
H
H
H
Methane
Ethane
Propane
Butane
Pentane
Hexane
Heptane
Octane
C
H
CH
H
H
H
H
C
H
CH
H
H
H
C
H
H
H
C
H
CH
H
H
H
C
H
C
H
H
H
H
C
H
CC
H
H
H
C
H
C
H
H
H
H
H
H
H
C
H
CC
H
H
H
C
H
C
H
H
H
H
H
C
H
H
H
H
C
H
CC
H
H
H
C
H
C
H
H
H
H
H
C
H
H
H
C
H
H
H
C
H
CC
H
H
H
C
H
C
H
H
H
H
H
C
H
H
H
C
H
H
C
H
H
H
C H
H
H
H CH4
C2H6
C3H8
C4H10
C5H12
C6H14
C7H16
C8H18
Molecular Formula
Full Structural Formula
Name of Alkane
Shortened Structural Formula
CH4
CH3CH2CH3
CH3CH3
CH3CH2CH2CH3
CH3CH2CH2CH2CH3
CH3CH2CH2CH2CH2CH3
CH3CH2CH2CH2CH2CH2CH3
CH3CH2CH2CH2CH2CH2CH2CH3
• The molecular formula tells you the number of carbon and hydrogen atoms in each molecule.
• The full structural formula shows relative position of the atoms in the molecule and the bonds holding the atoms together.
• The shortened structural formula does not show all of the bonds in the molecule.
The alkanes are a homologous series. This means that:
1.All alkanes can be represented by a general formula which is:
2.They all have similar chemical properties
3.There is a link between their physical properties and their melting and boiling points.
CnH2n+2
Alkanes – Homologous series
The following rhyme might help you to remember the order of the hydrocarbons.
•MMonkeys
•EEat
•PPeanut
•BButter
•PPieces
•HHorses
•HHave
•OOats
Branched AlkanesBranched Alkanes• Branched: When not all of the carbon atoms
are in a straight chain.
C
H
H
H
C
H
H
C
H
H
H
C
H
H
H
C
H
H
H
C
H
H
C
H
H
H
C
H
H
CH
butane 2-methylpropane
Each molecule has:
Same molecular formula but a different structural formula
Different names
Naming Branched AlkanesNaming Branched Alkanes
Rules
1. Look for the longest carbon atom chain to give the name of the alkane.
2. Number the carbon atoms from the end closest to the branch.
3. Identify the branch- CH3 is a Methyl group C2H5 is an Ethyl group
4. Use prefixes to indicate how many of a particular branch (di-2, tri-3)
5. Show the position of each branch with a number placed in front of its name.
6. If more than one branch, names are put in alphabetical order (ethyl before methyl).
Example 1Example 1
Methyl branch
Number carbon atoms from one end closest to branch 2 Methyl butane
1 2 3 4
Example 2Example 2
C C C C C
C
C
C
1 3 642 5
Methyl branch
Ethyl branch
3 Ethyl, 2 Methyl hexane
Example 3Example 3Methyl branch
Methyl branch123
2,2-dimethyl propane
Drawing structures from Drawing structures from systematic namessystematic names
Example 1 3-methyl pentane
1 2 3 4 5
Example 2 4 ethyl, 2,2 dimethyl octane
C C C C C C C C
C
C
C
C
1 2 3 87654
Name the following structures
1.
2.
3.
4-ethyl-2-methylhexane
3-ethyl-4-methylhexane
4-ethyl-3,3-dimethylheptane
Draw the following structures
Draw a structural formula for each of the following alkanes
1. 3-ethylhexane
1. 2, 2, 4-trimethylpentane
1. 2-methyl, 3-ethylheptane
1. 4, 4-dimethyloctane
Lesson Starter1. State the bonding present in alkanes.
2. State the name of the third member of the alkanes.
3. State the molecular formula of the sixth member of the alkanes.
4. Draw the molecular structure of pentane.
5. State the general formula for the alkanes.
Same second name
Homologous series
Look similar
Aims:
Discuss the Alkenes, which are a family of hydrocarbons.
The name for alkenes up to C8.
The structural formula for the alkenes up to C8.
The molecular formula for the alkenes up to C8.
The general formula for the alkene family.
Ethene C2H4
Propene C3H6
The AlkenesThe Alkenes• The alkenes contain a carbon to carbon
double bond and so they are called unsaturated hydrocarbons.
• The names of all members end in ‘ene’.• The alkenes generally have lower melting and
boiling points than their equivalent alkanes. The smaller alkenes are gases, but as the molecules increase in size they become liquids and eventually solids.
• Their melting and boiling points also increase as we move from ethene hexene.
Name of Alkene
Molecular Formula
Full Structural Formula
Shortened Structural Formula
Ethene
Propene
Butene
Pentene
Hexene
C2H4
C3H6
C4H8
C5H10
C6H12
CH2=CH2
CH2=CHCH3
CH2=CHCH2CH
3
CH2=CHCH2CH2CH
3
CH2=CHCH2CH2CH2CH3
1. The alkenes can also be represented by a general formula which is:
2. They all have similar chemical properties3. There is a link between their physical
properties and their melting and boiling points.
CnH2n
Alkenes – Homologous series
Naming Straight Chain AlkenesNaming Straight Chain Alkenes
Rules1.Identify the longest carbon chain.2.Number carbon atoms starting at the
end nearest the double bond.3.Identify the number of the carbon atom
where the double bond starts, and insert it into the name.
ExamplesExamples1. 2.
3. 4.
But-1-ene But-2-ene
Hex-3-ene 2 MethylProp-1-ene
Starter1. What is the general formula of the
alkanes?
2. What is the general formula of the alkenes?
3. How can you distinguish between the alkanes and the alkenes?
4. What is the different between the bonding in these two families?
Aims:
1. Discuss the cycloalkane family.
2. Discuss isomers.
Homologous series
Look similar
Same first name
All ring structures
CycloalkanesCycloalkanes• The cycloalkanes are another series of
hydrocarbons.• The carbon atoms form a ring and all
carbon to carbon bonds are saturated (carbon to carbon single bonds).
Cyclopropane
C
C
C
HH
H
H
H
H
C3H6
Cyclobutane
C4H8C
C
C
C
H H
H
H
HH
H
H
Name of Cycloalkane
Molecular Formula
Full Structural Formula
Shortened Structural Formula
Cyclopropane
Cyclobutane
Cyclopentane
Cyclohexane
C3H6
C4H8
C5H10
C6H12
CH2
CH2
CH2
CH2
CH2
CH2CH2
CH2
CH2
CH2
CH2
CH2
CH2 CH2
CH2
CH2
CH2
CH2
Cycloalkanes – Homologous Cycloalkanes – Homologous seriesseries1.All alkanes can be represented by a
general formula which is:
2.They all have similar chemical properties
3.There is a link between their physical properties and their melting and boiling points.
CnH2n
Isomers-Same molecular formula but
different structural formula.
e.g. C3H6 is the molecular formula for … Propene Cyclopropane
and
C
C
C
HH
H
H
H
H
Butene and cyclobutane are isomers because they both have the molecular formula C4H8 but their structures are different.
There are two isomers of butane, both with the molecular formula C4H10.
Butane 2-methylpropane
The larger the hydrocarbon, the more isomers are possible.
Can you try to draw 3 isomers for pentane?
Quick Quiz
1. What is the molecular formula for
cyclopentane?
2. Draw the structure of cyclobutane.
3. What is an isomer?
4. Draw three isomers of pentane.
Starter1. Name the 6th member of the alkanes.2. Name the 1st member of the alkenes.3. Name the 2nd member of the
cycloalkanes.4. What is the general formula for the
cycloalkanes?5. What bonding is present in the
cycloalkanes?6. What is a homologous series?
Saturated or UnsaturatedSaturated or Unsaturated• Saturated hydrocarbon: • a hydrocarbon that contains carbon to
carbon single covalent bonds only. • Alkanes and cycloalkanes are saturated
compounds
• Unsaturated hydrocarbon: • a hydrocarbon that contains at least one
carbon to carbon double covalent bond.• Alkenes are unsaturated compounds
Testing for UnsaturationTesting for Unsaturation
• Bromine water is used in order to determine whether an unknown hydrocarbon is saturated or unsaturated.
• Saturated hydrocarbons will have no effect on bromine water.
Unsaturated hydrocarbons rapidly turn orange/brown bromine water colourless.
Addition ReactionsAddition Reactions
• A C=C is very reactive and will easily break to give a carbon-to-carbon single covalent bond.
When Addition occurs…
alkene + hydrogen alkanee.g.
ethene + hydrogen ethane
+ H2 C
H
CH
H
H
H
H
Carbon to carbon double bond breaks. Bond between hydrogen molecule breaks and H atoms will join across the double bond.
Butene + H2 Butane
+ H2 C
H
CH
H
H
H
C
H
C
H
H
H
H
Addition of hydrogen is also called hydrogenation.
Addition of bromine - Bromination
1,2 dibromopropane (saturated)
The bromine molecule adds on across the double bond to give a Br atom on each atom either side of where the double bond used to be.
Addition of Water - Addition of Water - HydrationHydration
Adding water to an alkene gives the corresponding alcohol.
Alkene + water Alcohol
H-OH (H2O)
Making Plastics
• The most important use of alkenes and alkene derivatives is as feed stocks for the plastics industry…This is dealt with in Unit 3 (additional polymerisation)…so we will leave it till.
Everyday consumer products
•Energy from fuels
•Alcohols
•Carboxylic acids
•Esters
Contents
AlkanolsAlkanols(Alcohols)(Alcohols)
Alcohols• Look like alkanes but contain a hydroxyl
(OH) group.• names similar to alkanes but ending in
‘OL’, and each contains the hydroxyl group, OH, in place of a hydrogen atom.
e.g. second alcohol is ethanol (C2H5OH)
Shortened structural formula: CH3CH2OH
Name of alkanol
Molecular formula
Full structural Formula
Shortened structural formula
Methanol
Ethanol
Propanol
Butanol
Pentanol
Hexanol
Heptanol
Octanol
CH3OH
C2H5OH
C3H7OH
C4H9OH
C5H11OH
C6H13OH
C7H15OH
C8H17OH
CH3OH
CH3CH2OH
CH3CH2CH2OH
CH3CH2CH2CH2OH
CH3CH2CH2CH2CH2OH
CH3CH2CH2CH2CH2CH2OH
CH3CH2CH2CH2CH2CH2CH2OH
CH3CH2CH2CH2CH2CH2CH2CH2OH
Naming AlkanolsNaming AlkanolsRules1. Longest chain containing OH gives
alkane name (replace e with ol)2. Number carbon atoms in the chain
start from the end closest to the OH.3. For chains of 3 or more carbons name
the position of the OH must be given.4. Any branches must be named and
numbered.
Propan-2-ol
Dehydration of AlkanolsDehydration= removal of water
Alcohol equivalent Alkene + water
Butan-1-ol But-1-ene + water
O
HH+
Alkanoic AcidsAlkanoic Acids
• They look like alkanes but contain a carboxyl (COOH) group.
• Same names as alkanes but end in “oic”.
e.g. first alkanoic acid is METHANOIC ACID.
e.g. Full structural formula
HCOOH
Or
HCO2H
Shortened structural formula
Carboxyl functional group
Name of alkanoic acid
Molecular formula
Full structural formula
Shortened structural formula
Methanoic acid
HCOOH
Ethanoic acid
CH3COOH
Propanoic acid
C2H5COOH
Butanoic acid
C3H7COOH
HCOOH
CH3COOH
CH3CH2COOH
CH3CH2CH2COOH or
CH3(CH2)2COOH
Name of alkanoic acid
Molecular formula
Full structural formula
Shortened structural formula
Pentanoic acid
C4H9COOH
Hexanoic acid
C5H11COOH
Heptanoic acid
C6H13COOH
Octanoic acid
C7H15COOH
CH3-(CH2)3-COOH
CH3-(CH2)4-COOH
CH3-(CH2)5-COOH
CH3-(CH2)6-COOH
Naming Alkanoic AcidsNaming Alkanoic Acids
Rules1.Count the number of atoms in the
carbon chain to give the name of the parent alkanol.
2. Remove the –ol ending of the parent alkanol and replace it by –oic acid.
Esters
EstersAre covalent compounds that contain
carbon, hydrogen and oxygen.
Have a characteristic smells (e.g. pear
drops)
Are insoluble in water.
names end in –OATE and contain the ester
linkage –COO-, shown below.
O
CO
Formation of estersFormation of esters
Esters are the products of reactions
between carboxylic acids (alkanoic acids)
and alcohols (alkanols).
The alkanol loses an –H and the
alkanoic acid loses the –OH group.
molecules join together to form an ester
molecule with a water molecule.
the reaction between ethanoic acid and methanol can be represented as
shown:
methanol
(alkanol)
ethanoic acid
(alkanoic acid)
C H 3 C
O
O H H O C H 3
C H 3 C
O
O C H 3
+ H2O
ester
Ester link
Ethanoic Acid
Water
Ethanol
Ethyl Ethanoate
Ester link
Naming Esters
1. The names for esters are based on the alkanol and alkanoic acid from which they are made.
2. Esters names are usually written as two words of the type alkyl alkanoate.
3. The first part of the name comes from the alkanol with the –ol ending removed and –yl added.
4. The second part of the name comes from the alkanoic acid with the –oic acid ending changed to –oate.
Alkanol Alkanoic acid Name of ester
Methanol Methanoic acid Methyl methanoate
Ethanol Methanoic acid Ethyl methanoate
Methanol Ethanoic acid Methyl ethanoate
Ethanol Ethanoic acid Ethyl ethanoate
Methanol Propanoic acid Methyl propanoate
Ethanol Propanoic acid Ethyl propanoate
Reactions of Carbon Reactions of Carbon CompoundsCompounds
Many hydrocarbons take part in chemical reactions.
We have already discussed 1-31. Addition2. Cracking3. Production of Ethanol 4. Making and Breaking Esters
Making and Breaking Esters
Making EstersMaking Esters
• Esters are made by a condensation reaction between carboxylic acid and an alcohol.
• This can also be called an esterification reaction.
• In this reaction a water molecule is eliminated from the functional groups of the carboxylic acid (COOH) and alcohol (OH).
An ester link is formed by the reaction of the hydroxyl (OH) functional group and the carboxyl (COOH) functional group.
CH3 C
O
OH CH3OH
CH3 C
O
O CH3
H OH
+
+
Ester link
• Condensation reaction is slow at room temperature and yield of the ester is low.
• Rate can be increased by heating reaction mixture and by using concentrated sulphuric acid as a catalyst.
• Evidence that an ester is formed is its typical sweet smell, and that is appears as a solid/oily liquid on the water.
• The process is reversible i.e it operates in both directions. This means it is possible to break the ester down to the alkanol and alkanoic acid that made it.
Breaking EstersBreaking Esters
• An ester can be broken down into its parent alcohol and carboxylic acid.
• This involves heating the ester with water and so it is called a hydrolysis reaction.
• Hydrolysis reactions are the reverse of condensation reactions.
• This is also a reversible reaction.
Remember...Remember...
• Condensation reaction makes an ester
and water is formed.
• Hydrolysis reaction breaks an ester and
water is used up.
• These are reverse reactions.