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AS Chemistry. Bonding in methane, ethane and ethene and bonds. Learning Objectives Candidates should be able to: describe covalent bonding in terms of orbital overlap, giving and bonds. - PowerPoint PPT Presentation
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Bonding in methane, ethane
and ethene and bonds
AS Chemistry
Learning Objectives
Candidates should be able to:
•describe covalent bonding in terms of orbital overlap, giving and bonds.
•explain the shape of, and bond angles in, ethane and ethene molecules in terms of and bonds.
Starter activity
Alkenes
pent-2-ene CH3CH=CHCH2CH3
hex-3-ene CH3CH2CH=CHCH3
2,3-dimethylpent-2-ene
cyclopenta-1,3-diene
3-ethylhept-1-ene CH2=CHCH2CH(CH2CH3)CH2CH2CH3
Hybridisation of orbitals
The electronic configuration of a carbon atom is 1s22s22p2
1 1s
2
2s
2p
HYBRIDISATION OF ORBITALS
If you provide a bit of energy you can promote (lift) one of the s electrons into a p orbital. The configuration is now 1s22s12p3
1 1s
2
2s
2p
The extra energy released when the bonds form more than compensates for the initial input.
Hybridisation of orbitals in alkanesThe four orbitals (an s and three p’s) combine or HYBRIDISE to give four new orbitals. All four orbitals are equivalent.
Because one s and three p orbitals are used, it is called sp3 hybridisation.
2s22p2 2s12p3 4 x sp3
sp3 orbitals
In ALKANES, the four sp3 orbitals repel each other into a tetrahedral arrangement.
Hybridisation of orbitals in alkanes
Bonding in methane
Bonding in ethane
Bonding in ethene
Alternatively, only three orbitals (an s and two p’s) combine or HYBRIDISE to give three new orbitals. All three orbitals are equivalent. The remaining 2p orbital is unchanged.
2s22p2 2s12p3 3 x sp2 2p
sp2 hybrids
What about ethene?
- bonds
Geometric Isomerism
AS Chemistry
Learning Objectives
Candidates should be able to:
describe cis-trans isomerism in alkenes, and explain its origin in terms of restricted rotation due to the presence of π bonds.
deduce the possible isomers for an organic molecule of known molecular formula.
identify cis-trans isomerism in a molecule of given structural formula.
Starter activity
ISOMERISM
STRUCTURAL ISOMERISM STEREOISOMERISM
GEOMETRIC ISOMERISM OPTICAL ISOMERISM
What is stereoisomerism?
In stereoisomerism, the atoms making up the isomers are joined up in the same order, but still manage to have a different arrangement in space
Geometric Isomerism?
GEOMETRIC ISOMERISMRESTRICTED ROTATION OF C=C BONDS
Single covalent bonds can easily rotate. What appears to be a different structure in an alkane is not. Due to the way structures are written out, they are the same.
ALL THESE STRUCTURES ARE THE SAME BECAUSE C-C BONDS HAVE ‘FREE’ ROTATION
Animation doesn’t work in old versions of Powerpoint
Geometric Isomerism?
Geometric isomers of but-2-ene
X
Geometric Isomerism?
GEOMETRIC ISOMERISMHow to tell if it exists
Two different atoms/groups attached
Two different atoms/groups attached
Two similar atoms/groups attached
Two similar atoms/groups attached
Two similar atoms/groups attached
Two different atoms/groups attached
Two different atoms/groups attached
Two different atoms/groups attached
GEOMETRICAL ISOMERISM
GEOMETRICAL ISOMERISM
Once you get two similar atoms/groups attached to one end of a C=C, you cannot have geometrical isomerism
GEOMETRIC ISOMERISMIsomerism in butene
There are 3 structural isomers of C4H8 that are alkenes*. Of these ONLY ONE exhibits geometrical isomerism.
BUT-1-ENE 2-METHYLPROPENE
trans BUT-2-ENEcis BUT-2-ENE
* YOU CAN GET ALKANES WITH FORMULA C4H8 IF THE CARBON ATOMS ARE IN A RING
Summary
To get geometric isomers you must have:
restricted rotation (involving a carbon-carbon double bond for A-level purposes);
two different groups on the left-hand end of the bond and two different groups on the right-hand end. It doesn't matter whether the left-hand groups are the same as the right-hand ones or not.
The effect of geometric isomerism on physical properties
isomermelting point (°C)
boiling point (°C)
cis -80 60
trans -50 48
You will notice that:the trans isomer has the higher melting point;the cis isomer has the higher boiling point.
Why is the boiling point of the cis isomers higher?
The difference between the two is that the cis isomer is a polar molecule whereas the trans isomer is non-polar.
Why is the melting point of the cis isomers lower?
In order for the intermolecular forces to work well, the molecules must be able to pack together efficiently in the solid.
Trans isomers pack better than cis isomers. The "U" shape of the cis isomer doesn't pack as well as the straighter shape of the trans isomer.
Optical Isomerism
AS Chemistry
Learning Objectives
Candidates should be able to:
explain what is meant by a chiral centre and that such a centre gives rise to optical isomerism.
deduce the possible isomers for an organic molecule of known molecular formula.
identify chiral centres in a molecule of given structural formula.
Starter activity
Optical isomerism
When four different atoms or groups are attached to a carbon atom, the molecules can exist in two isomeric forms known as optical isomers. These are non-superimposable mirror images.
Chiral centre
Chiral molecule
Optical IsomerismWhat is a non-superimposable mirror image?
Animation doesn’t work in old versions of Powerpoint
Optical isomerism
Amino acids (the building blocks of proteins) are optically active. They affect plane polarised light differently.
Butan-2-ol
Optical IsomerismThe polarimeter
If the light appears to have turned to the right turned to the left DEXTROROTATORY LAEVOROTATORY
A Light source produces light vibrating in all directionsB Polarising filter only allows through light vibrating in one directionC Plane polarised light passes through sampleD If substance is optically active it rotates the plane polarised lightE Analysing filter is turned so that light reaches a maximumF Direction of rotation is measured coming towards the observer
A B
C DE
F
Enantiomers – how do they differ?
Usually have the same chemical and physical properties – but behave differently in presence of other chiral compounds.
Enantiomers – how do they differ?
TYPES OF ISOMERISM
Occurs due to the restricted rotation of C=C double bonds... two forms - CIS and TRANS
STRUCTURAL ISOMERISM
STEREOISOMERISM
GEOMETRICAL ISOMERISM
OPTICAL ISOMERISM
CHAIN ISOMERISM
Same molecular formula but different structural formulae
Occurs when molecules have a chiral centre. Get two non-superimposable mirror images.
Same molecular formula but atoms occupy different positions in space.
POSITION ISOMERISM
FUNCTIONAL GROUP ISOMERISM
Electrophilic Addition to
Alkenes
AS Chemistry
Learning Objectives
Candidates should be able to:
• describe the mechanism of electrophilic addition in alkenes, using bromine/ethene as an example.
• describe the chemistry of alkenes as exemplified, where relevant, by the following reactions of ethene: addition of hydrogen, steam, hydrogen halides and halogens.
Starter activity
CH2=CH2 + Br2 CH2BrCH2Br
Electrophilic addition
Electrophilic addition
CH2=CH2 + Br2 CH2BrCH2Br
bromine with ethene
hydrogen bromide with ethene
CH2=CH2 + HBr CH3CH2Brbromoethane
1,2-dibromoethane
Br
Br
Br
Br
Electrophilic addition mechanism
H
H H
H
CC
+
-
H
H H
HCC
Br+
Br-
carbocation
H
H H
HCC
Br Br1,2-dibromoethane
bromine with ethene
Electrophilic addition mechanism
H
H H
H
CC
H
H H
HCC
H+
carbocation
H
H H
HCC
Br H
bromoethane
hydrogen bromide with ethene
-
+
Br
H
Br-
Electron flow during electrophilic addition
EQUATION TEMPERATUR
E(OC)
PRESSURE CATALYST PHASE NOTES
hydrogen CH2=CH2 + H2 → CH3CH3 ~150
Finely divided nickel on support material
GasNever carried out industrially. Analogous reaction used to produce some margarines from oils (see later).
steam CH2=CH2 + H2O→ CH3CH2OH
330 6MPaPhosphoric (V) acid (H3PO4) adsorbed onto the surface of silica.
GasMajor industrial process for the manufacture of ethanol.
hydrogen halides
(e.g. HBr)
CH2=CH2 + HBr → CH3CH2Br
Room temperature
Aqueous solution
Reactivity increases from HF to HI.
halogens CH2=CH2 +Br2→ CH2BrCH2Br
Room temperature
Liquid bromine or solution (both aqueous and non-polar solvent.
Chlorine and iodine produce similar addition products. Fluorine is too powerful an oxidizing agent.Addition reactions of
alkenes
Addition to unsymmetrical alkenesElectrophilic addition to propene
2-bromopropane
1-bromopropane
In the electrophilic addition to alkenes the major product is formed via the more stable carbocation (carbonium ion)
least stable most stable
methyl < primary (1°) < secondary (2°) < tertiary (3°)
Addition to unsymmetrical alkenes
PATH A
PATH B
MAJOR PRODUCT
PRIMARYCARBOCATION
SECONDARYCARBOCATION
MINOR PRODUCT
Addition to unsymmetrical alkenes
Polymerisation
AS Chemistry
Learning Objectives
Candidates should be able to:
describe the chemistry of alkenes including polymerisation.
describe the characteristics of addition polymerisation as exemplified by poly(ethene) and PVC.
Recognize the difficulty of the disposal of poly(alkene)s, i.e. non-biodegradability and harmful combustion products.
Starter activity
Poly(ethene)
Temperature: about 200°C
Pressure: about 2000 atmospheres
Initiator: often a small amount of oxygen as an impurity
Conditions
Free radical addition
Initiation
Propagation
Termination
Propagation
LDPE or HDPE
LDPE or HDPE
Freezer bags, water pipes, wire and cable insulation, extrusion coating
Sandwich bags, cling wrap, car covers, squeeze bottles, liners for tanks and ponds, moisture barriers in construction
Polymerisation of alkenes
ETHENE POLY(ETHENE)
TETRAFLUOROETHENE
POLY(TETRAFLUOROETHENE)
PTFE “Teflon”
PROPENE POLY(PROPENE)
CHLOROETHENEPOLY(CHLOROETHENE)
POLYVINYLCHLORIDE PVC
Method CommentsLandfill Emissions to the atmosphere and
water; vermin; unsightly. Can make use of old quarries.
Incineration Saves on landfill sites and produces energy. May also release toxic and greenhouse gases.
Recycling high cost of collection and re-processing.
Feedstock recycling
Use the waste for the production of useful organic compounds. New technology can convert waste into hydrocarbons which can then be turned back into polymers.
Disposal of polymers
Oxidation of alkenes
AS Chemistry
Learning Objectives
Candidates should be able to describe the oxidation of alkenes by:
cold, dilute, acidified manganate(VII) ions to form the diol, and
hot, concentrated, acidified manganate(VII) ions leading to the rupture of the carbon-to-carbon double bond in order to determine the position of alkene linkages in larger molecules.
Starter activity
Oxidation of alkenes
In the presence of dilute (acidified or alkaline) potassium manganate (VII).
•Alkenes react readily at room temperature (i.e. in the cold).
•The purple colour disappears and a diol is formed.
CH2=CH2 + H2O + [O] HOCH2CH2OHethane – 1,2-diol
Oxidation of alkenes
Fragment Product
=CH2CO2
R-CH=
Aldehyde → carboxylic acid
R2C=Ketone
In the presence of a hot, concentrated solution of acidified potassium manganate (VII), any diol formed is split into two fragments which are oxidized further to carbon dioxide, a ketone or a carboxylic acid.
Oxidation of alkenes1. CH2=CH2
2. CH3CH=CH2
3. (CH3)2C=CH2
2 products – both contain ketone
2 products – one contains 2 ketone groups and one contains 2 acid groups.
1 product only
Halogenoalkanes
AS Chemistry
Learning Objectives
Candidates should be able to recall the chemistry of halogenoalkanes as exemplified by the following nucleophilic substitution reactions of bromoethane:
hydrolysis;
formation of nitriles;
formation of primary amines by reaction with ammonia.
Starter activity
a. CHCl3 trichloromethaneb. CH3CHClCH3 2-chloropropanec. CF3CCl3 1,1,1-trichloro-2,2,2-
trifluoroethane
Naming Halogenoalkanes
F
F
Cl
Cl
F Cl
Physical Propertiesa. 1-chloropropane is polar and has permanent
dipole-dipole intermolecular forces that are stronger than the temporary dipole-induced dipole forces in non-polar butane.
b. 1-chloropropane is polar and has permanent dipole-dipole intermolecular forces that are stronger than the temporary dipole-induced dipole forces in non-polar butane.
Nucleophilic substitution negotiate clever
alp or
cadet tart
eat given
enticed if
chenille soup
had lie
stubs tuition
electronegative
polar
attracted
negative
deficient
nucleophiles
halide
substitution
Nucleophilic substitution
This is known as an SN2 reaction. S stands for substitution,
N for nucleophilic, and
2 because the initial stage of the reaction involves two species.
Nucleophilic substitution - mechanism
ANIMATION SHOWING THE SN2 MECHANISM
Attack by nucleophile is to the back of the molecule – away from the negatively charged halogen atom.
Rate of reaction
You may expect the fluoroalkane to react more quickly as the C-F bond is the most polar and therefore more susceptible to attack by nucleophiles. However, the C-F bond is the strongest. A nucleophile may be more attracted more strongly to the carbon atom but, unless it forms a stronger bond to carbon, it will not displace the halogen.
Actually the reaction with the iodoalkane is the most rapid. This suggests that the strength of the C-X bond is more important than its polarity. Note that the C-I bond is not polar. However, it is easily polarisable.
Halogen F Cl Br IElectronegativity 4.0 3.0 2.8 2.5
Bond strength (C-X) kJ mol-1
484 338 276 238
Experiment
Water is a poor nucleophile but it can slowly displace halide ions C2H5Br(l) + H2O(l) C2H5OH(l) + H+
(aq) + Br¯(aq)
If aqueous silver nitrate is shaken with a halogenoalkane (they are immiscible) the displaced halide combines with a silver ion to form a precipitate of a silver halide. The weaker the C-X bond the quicker the precipitate appears.
Measuring the rate of reaction
hydroxide ion with bromoethane
ethanolCH3CH2Br + OH- CH3CH2OH + Br-
(aqueous)
Nucleophilic substitution
Water with bromoethane
ethanolCH3CH2Br + H2O CH3CH2OH + HBr(aqueous)
This is a slower reaction – water is not such a good nucleophile.
warm
warm
+ -CH3
H
BrC
H
-OH
CH3
H
OHC
H Br-
hydroxide ion with bromoethane
Nucleophilic substitution mechanism
ethanol
water with bromoethane
Nucleophilic substitution mechanism
ethanol
+ -CH3
H
BrC
H
Br-
H
CH3
H
OHC
H
+
CH3
H
OHC
HHBr
H2O
propanenitrile
CH3CH2Br + CN-(ethanol) CH3CH2CN + Br-
cyanide ion with bromoethane
ammonia with bromoethane
CH3CH2Br + NH3(ethanol) CH3CH2NH22 + NH4+Br-
Nucleophilic substitution
aminoethane
CH3CH2Br + NH3(ethanol)CH3CH2NH2 + HBr
reflux
Heat /
pressure
Heat /
pressure
+ -CH3
H
BrC
H
CN-
CH3
H
CNC
H Br-
cyanide ion with bromoethane
Nucleophilic substitution mechanism
propanenitrile
ammonia with bromoethane
Nucleophilic substitution mechanism
aminoethane
+ -CH3
H
BrC
H
Br-
H
CH3
H
NH2C
H
+
CH3
H
NH2C
H
NH3
H NH3+Br -
NH3
Past paper question
Cl2U.V. /sunlight
Ethanolic KCNreflux
Br2
U.V. /sunlight
Substitution vs. Elimination
AS Chemistry
Learning Objectives
Candidates should be able to:
recall the chemistry of halogenoalkanes as exemplified by the elimination of hydrogen bromide from 2-bromopropane.
describe the mechanism of nucleophilic substitution (by both SN1 and SN2 mechanisms) in halogenoalkanes.
Starter activity
Type of halogenoalkan
e
Position of halogeno-
group
Example
primary at end of chain: bromoethane
secondary in middle of chain: 2-bromopropane
tertiary attached to a carbon atom which carries no H atoms:
2-bromo-2-methylpropane
SN1 – tertiary halogenoalkanes
Nucleophilic attack at the back of the molecule is hindered by bulky CH3 groups. Tertiary carbocation is stabilised by electron donating effect of CH3 groups.
SN1 or SN2 ?
Halogenoalkane Mechanism
Primary SN2
Secondary SN1 and SN2
Tertiary SN1
Elimination
You need to be aware that the hydroxide ion can act as a strong base as well as a nucleophile.
An alternative reaction can take place in which HBr is removed and an alkene is formed. This is known as elimination.
CH3CH2Br + NaOH CH2=CH2 + NaBr + H2O
Elimination of HBr from 2-bromopropane
CH3
H H
H
CC
OH-
CH3
H H
HCC
Br H
propene
H OHBr -
CH3CHBrCH3 + OH- CH3CH=CH2 + H2O + Br-
(in ethanol)
acting as a base
Elimination of HX from haloalkanes
92
elimination
+ OH-
RCH=CH2 + H2O + X-
(ethanol)
nucleophilic substitutionalcohol
+ OH-
RCH3CH2OH + Br-
(aqueous)
RCH2CH2X
alkene
hydroxide acts as a base
hydroxide acts as a nucleophile
Substitution or Elimination?
AS Chemistry
Pros and Cons
Learning ObjectivesCandidates should be able to:
interpret the different reactivities of halogenoalkanes e.g. CFCs; anaesthetics; flame retardants; plastics with particular reference to hydrolysis and to the relative strengths of the C-Hal bonds;
explain the uses of fluoroalkanes and hydrofluorooalkanes in terms of their relative chemical inertness;
recognise the concern about the effect of chlorofluoroalkanes on the ozone layer.
Starter activity
Chlorofluorocarbons - CFCs
. Properties:
Non-flammable
Low toxicity
Unreactive
Liquefy easily when compressed
Uses
Refrigerants
Propellants for aerosols
Solvents (including dry-cleaning)Degreasers
The ozone layer
Natural ozone layer
Replacements
•Hydrochlorofluorocarbons, HCFCs: shorter life in the atmosphere.
•Hydrofluorocarbons, HFCs: don’t contain chlorine so zero affect on ozone layer.
•Hydrocarbons: zero effect on ozone layer but flammable and lead to photochemical smog.
C. Why is BCF good at extinguishing fires?
The presence of a bromine confers flame – retarding qualities on the product.
The high temperature in fires break this compound down, producing free radicals such as Br∙. These react with other free radicals produced during combustion, quenching the flames.
