Similar presentations:
Edexcel organic reaction mechanisms
1. Edexcel organic reaction mechanisms
Click a box below to go to the mechanismHomolytic
Click
here for
advice
Free Radical Substitution
Free Radical Addition
Heterolytic
Electrophilic Addition
Nucleophilic Substitution
Electrophilic Substitution
SN2
Nitration
S N1
Br2
Alkylation
Acylation
Nucleophilic Addition
Original slide
prepared for the
2. Free radical substitution
chlorination of methanei.e. homolytic breaking of covalent bonds
Overall reaction equation
CH4 + Cl2
CH3Cl + HCl
Conditions
ultra violet light
excess methane to reduce further substitution
Original slide
prepared for the
3. Free radical substitution mechanism
ClH3C
H3C
H3C
H3C
Cl
ultra-violet
H
Cl
Cl
Cl
initiation step
Cl
H3C
H
Cl
Cl
H3C
Cl
Cl
Cl
H3C
Cl
CH3
H3C
CH3
two
propagation
steps
termination step
minor
termination step
Original slide
prepared for the
4. Further free radical substitutions
Overall reaction equationsCH3Cl + Cl2
CH2Cl2 + HCl
CH2Cl2 + Cl2
CHCl3 + HCl
CHCl3 + Cl2
CCl4 + HCl
Conditions
ultra-violet light
excess chlorine
Original slide
prepared for the
5. Free radical addition
addition polymerisation of ethenei.e. homolytic breaking of covalent bonds
Overall reaction equation
n H2C=CH2
ethene
[ CH2CH2 ]n
polyethene
Conditions
free radical source
(a species that generates free radicals
that allow the polymerisation of ethene molecules)
Original slide
prepared for the
6. Free radical addition mechanism
RH2C
H2C
CH2
CH2
R
R
R
R
H2C
H2C
initiation step
CH2
R
H2C
CH2R
CH2
CH2CH2R
chain propagation steps
Addition of H2C=CH2 repeats the same way until:
R(CH2)nCH2
H2C(CH2)mR
termination step
R(CH2)nCH2
CH2(CH2)mR
polyethene
Original slide
prepared for the
7. Electrophilic addition
bromine with propeneCH3CH=CH2 + Br2
mechanism
CH3CHBrCH2Br
1,2-dibromopropane
hydrogen bromide with but-2-ene
CH3CH=CHCH3+ HBr
mechanism
CH3CH2CHBrCH3
2-bromobutane
Original slide
prepared for the
8. bromine with propene
Electrophilic addition mechanismbromine with propene
H
reaction equation
H
C C
CH3
H
+
Br
Br
-
H
H
carbocation
CH3 C
+
C
H
Br
H
H
Br
CH3 C
C
Br
Br
1,2-dibromopropane
Br-
H
Br
Original slide
prepared for the
9. hydrogen bromide with trans but-2-ene
Electrophilic addition mechanismhydrogen bromide with trans but-2-ene
reaction equation
CH3
H
C C
CH3
H
H
+
Br
-
H
H
carbocation
CH3 C
+
C
CH3
Br-
H
H
H
CH3 C
C
Br
H
CH3
2-bromobutane
Original slide
prepared for the
10. Nucleophilic substitution
hydroxide ion with bromoethaneCH3CH2Br + OH- (aqueous)
mechanism
CH3CH2OH + Brethanol
hydroxide ion with 2-bromo,2-methylpropane
mechanism
(CH3)3CBr+ OH- (aqueous)
(CH3)3COH + Br2-methylpropan-2-ol
Original slide
prepared for the
11. hydroxide ion with bromoethane (SN2)
Nucleophilic substitution mechanismhydroxide ion with bromoethane
H
+
CH3 C
H
Br
CH3 C
H
OH-
(SN2)
OH
H
S N2
Br
ethanol
reaction equation
S (substitution) N(nucleophilic) 2(species reacting
in the slowest step)
Original slide
prepared for the
12. OH- ion with 2-bromo,2-methylpropane (SN1)
Nucleophilic substitution mechanismOH- ion with 2-bromo,2-methylpropane
(SN1)
-
CH3
+
CH3 C Br
CH3
Br
CH3 C+
CH3 C
CH3
CH3
S N1
CH3
Br
OH
CH3
OH-
2-methylpropan-2-ol
reaction equation
S (substitution) N(nucleophilic) 1(species reacting
in the slowest step)
Original slide
prepared for the
13. Nucleophilic substitution
cyanide ion with iodoethaneCH3CH2I (ethanol) + CN-(aq)
mechanism
CH3CH2CN + Ipropanenitrile
cyanide ion with 2-bromo,2-methylpropane
mechanism
(CH3)3CBr (ethanol) + CN- (aqueous)
(CH3)3CCN + Br2,2-dimethylpropanenitrile
Original slide
prepared for the
14. cyanide ion with iodoethane (SN2)
Nucleophilic substitution mechanismcyanide ion with iodoethane (SN2)
H
+
CH3 C
I
H
-
CH3 C
H
CN-
CN
H
I
-
propanenitrile
SN2
S (substitution) N(nucleophilic) 2(species reacting
in the slowest step)
reaction equation
Original slide
prepared for the
15. CN- ion with 2-bromo,2-methylpropane (SN1)
Nucleophilic substitution mechanismCN- ion with 2-bromo,2-methylpropane
(SN1)
-
CH3
+
CH3 C Br
CH3
CH3
Br
CH3 C+
CH3 C
CH3
S N1
CH3
Br
CN
CH3
CN-
2,2-dimethyl
propanenitrile
S (substitution) N(nucleophilic) 1(species reacting
in the slowest step)
reaction equation
Original slide
prepared for the
16. Electrophilic Substitution
Nitration of benzeneWhere an H atom attached to an aromatic ring
is replaced by an NO2 group of atoms
C6H6
+ HNO3
C6H5NO2
+ H2O
Conditions / Reagents
concentrated HNO3 and concentrated H2SO4
50oC
mechanism
Original slide
prepared for the
17. electrophilic substitution mechanism (nitration)
+1. Formation of NO2 the nitronium ion
+
HNO3 + 2H2SO4
NO2
+ 2HSO4- + H3O+
2. Electrophilic attack on benzene
+
NO2
+
NO2
H
-
O SO3H
3. Forming the product
and re-forming the catalyst
reaction equation
NO2
H O SO3H
Original slide
prepared for the
18. Bromination of benzene
Where an H atom attached to an aromatic ringis replaced by a Br atom
electrophilic substitution
C 6 H6
+ Br2
C6H5Br
+ HBr
R = alkyl group
Conditions / Reagents
Br2
and anhydrous AlBr3
25oC
Original slide
prepared for the
19. Electrophilic substitution mechanism
1. Formation of the electrophileBr
Br
AlBr3
+
Br
2. Electrophilic attack on benzene
+
Br
Br
H
+
3. Forming the products
Br
-
AlBr3
-
Br
AlBr3
Br
and re-forming the catalyst
bromobenzene
H
Br
AlBr3
Original slide
prepared for the
20. Alkylation of benzene
Where an H atom attached to an aromatic ringis replaced by a C atom
electrophilic substitution
C 6 H6
+ RCl
C6H5R
+ HCl
R = alkyl group
Conditions / Reagents
RCl (haloakane)
and anhydrous AlCl3
0 - 25oC to prevent further substitution
Original slide
prepared for the
21. Alkylation example
With chloroethaneC6H6 + CH3CH2Cl
overall reaction equation
C6H5CH2CH3 + HCl
Three steps in electrophilic substitution mechanism
1. Formation of the electrophile (a carbocation)
CH3CH2
Cl
AlCl3
+
CH3CH2
Cl
-
AlCl3
Original slide
prepared for the
22. Alkylation electrophilic substitution mechanism 2
2. Electrophilic attack on benzene+
CH3CH2
CH3CH2
H
+
-
Cl
AlCl3
3. Forming the product
and re-forming the catalyst
CH3CH2
H
AlCl3
Cl
ethylbenzene
Original slide
prepared for the
23. Acylation of benzene
An H atom attached to an aromatic ringis replaced by a C atom where C is part of C=O
electrophilic substitution
C 6 H6
+ RCOCl
C6H5COR + HCl
Conditions / Reagents
RCOCl (acyl chloride) and anhydrous AlCl3
50 oC
Original slide
prepared for the
24. Acylation example
With ethanoyl chloride overall reaction equationC6H6 + CH3COCl
C6H5COCH3
+ HCl
Three steps in electrophilic substitution mechanism
1. Formation of the electrophile (an acylium ion)
O
CH3C
Cl
+
CH3C O
AlCl3
Cl
-
AlCl3
Original slide
prepared for the
25. Acylation electrophilic substitution mechanism 2
2. Electrophilic attack on benzeneO
+
CH3C O
CH3C
+
H
Cl
3. Forming the products
and re-forming the catalyst
O
CH3C
-
AlCl3
H
Cl
AlCl3
phenylethanone
Original slide
prepared for the
26. Nucleophilic Addition
addition of hydrogen cyanide to carbonylsto form hydroxynitriles
RCOR
+ HCN
RCHO + HCN
RC(OH)(CN)R
RCH(OH)CN
Conditions / Reagents
NaCN (aq) and H2SO4(aq) supplies H+
supplies the CN- nucleophile
Room temperature and pressure
Original slide
prepared for the
27. Nucleophilic Addition Mechanism
hydrogen cyanide with propanoneCH3COCH3 + HCN
CH3C(OH)(CN)CH3
NaCN (aq) is a source of cyanide ions
+
CH3 C
O
-
CH3
CN
H+ from H2SO4 (aq)
+
H
O
CH3 C
CH3
CN
C N
O
CH3 C
H
CN
CH3
2-hydroxy-2-methylpropanenitrile
Original slide
prepared for the
28. Advice
To get back to the mechanism links page from anywhere in thepresentation, click the
button at the top right corner of the screen.
This version provides the organic mechanisms specified (2002/3)
by the Edexcel exam board. Each stage of a reaction equation, its
conditions and mechanism are revealed in turn on a mouse click or
keyboard stroke. Note that there is another version available where each
reaction and mechanism play automatically after an initiating click or key
stroke.
The number of ways of navigating through this presentation may depend
on the version of PowerPoint being used and how it is configured.
Some possible ways of advancing:
left mouse click or return key or right arrow key or up arrow key.
Some possible ways of reversing:
backspace key or left arrow key or down arrow key.
Original slide
prepared for the
29. References
Steve Lewis for the Royal Society of ChemistryOriginal slide
prepared for the