benzene ppt
DESCRIPTION
this is really useful to people doing A2 chemistryTRANSCRIPT
THE CHEMISTRYTHE CHEMISTRYOF ARENESOF ARENESA guide for A level studentsA guide for A level students
KNOCKHARDY PUBLISHINGKNOCKHARDY PUBLISHING2008 2008
SPECIFICATIONSSPECIFICATIONS
INTRODUCTION
This Powerpoint show is one of several produced to help students understand selected topics at AS and A2 level Chemistry. It is based on the requirements of the AQA and OCR specifications but is suitable for other examination boards.
Individual students may use the material at home for revision purposes or it may be used for classroom teaching if an interactive white board is available.
Accompanying notes on this, and the full range of AS and A2 topics, are available from the KNOCKHARDY SCIENCE WEBSITE at...
www.knockhardy.org.uk/sci.htm
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either clicking on the grey arrows at the foot of each page
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ARENESARENESKNOCKHARDY PUBLISHINGKNOCKHARDY PUBLISHING
CONTENTS
• Prior knowledge
• Structure of benzene
• Thermodynamic stability
• Delocalisation
• Electrophilic substitution
• Nitration
• Chlorination
• Friedel-Crafts reactions
• Further substitution
ARENESARENES
Before you start it would be helpful to…
• know the functional groups found in organic chemistry
• know the arrangement of bonds around carbon atoms
• recall and explain electrophilic addition reactions of alkenes
ARENESARENES
STRUCTURE OF BENZENESTRUCTURE OF BENZENE
Primary analysis revealed benzene had...
an empirical formula of CH and
a molecular mass of 78 and
a molecular formula of C6H6
STRUCTURE OF BENZENESTRUCTURE OF BENZENE
Primary analysis revealed benzene had...
an empirical formula of CH and
a molecular mass of 78a molecular formula of C6H6
Kekulé suggested that benzene was...
PLANARCYCLIC and
HAD ALTERNATING DOUBLE AND SINGLE BONDS
STRUCTURE OF BENZENESTRUCTURE OF BENZENE
HOWEVER...
• it did not readily undergo electrophilic addition - no true C=C bond
• only one 1,2 disubstituted product existed
• all six C—C bond lengths were similar; C=C bonds are shorter than C-C
• the ring was thermodynamically more stable than expected
STRUCTURE OF BENZENESTRUCTURE OF BENZENE
HOWEVER...
• it did not readily undergo electrophilic addition - no true C=C bond
• only one 1,2 disubstituted product existed
• all six C—C bond lengths were similar; C=C bonds are shorter than C-C
• the ring was thermodynamically more stable than expected
To explain the above, it was suggested that the structure oscillatedbetween the two Kekulé forms but was represented by neither ofthem. It was a RESONANCE HYBRID.
THERMODYNAMIC EVIDENCE FOR STABILITYTHERMODYNAMIC EVIDENCE FOR STABILITY
When unsaturated hydrocarbons are reduced to the corresponding saturated compound, energy is released. The amount of heat liberated per mole (enthalpy of hydrogenation) can be measured.
THERMODYNAMIC EVIDENCE FOR STABILITYTHERMODYNAMIC EVIDENCE FOR STABILITY
2 3
- 120 kJ mol-1
When cyclohexene (one C=C bond) is reduced to cyclohexane, 120kJ of energy is released per mole.
C6H10(l) + H2(g) ——> C6H12(l)
When unsaturated hydrocarbons are reduced to the corresponding saturated compound, energy is released. The amount of heat liberated per mole (enthalpy of hydrogenation) can be measured.
THERMODYNAMIC EVIDENCE FOR STABILITYTHERMODYNAMIC EVIDENCE FOR STABILITY
2 3
- 120 kJ mol-1
Theoretical- 360 kJ mol-1
(3 x -120)
When cyclohexene (one C=C bond) is reduced to cyclohexane, 120kJ of energy is released per mole.
C6H10(l) + H2(g) ——> C6H12(l)
Theoretically, if benzene contained three separate C=C bonds it would release 360kJ per mole when reduced to cyclohexane
C6H6(l) + 3H2(g) ——> C6H12(l)
When unsaturated hydrocarbons are reduced to the corresponding saturated compound, energy is released. The amount of heat liberated per mole (enthalpy of hydrogenation) can be measured.
THERMODYNAMIC EVIDENCE FOR STABILITYTHERMODYNAMIC EVIDENCE FOR STABILITY
2 3
Experimental- 208 kJ mol-1- 120 kJ mol-1
Theoretical- 360 kJ mol-1
(3 x -120)
When cyclohexene (one C=C bond) is reduced to cyclohexane, 120kJ of energy is released per mole.
C6H10(l) + H2(g) ——> C6H12(l)
Theoretically, if benzene contained three separate C=C bonds it would release 360kJ per mole when reduced to cyclohexane
C6H6(l) + 3H2(g) ——> C6H12(l)
Actual benzene releases only 208kJ per mole when reduced, putting it lower down the energy scale
When unsaturated hydrocarbons are reduced to the corresponding saturated compound, energy is released. The amount of heat liberated per mole (enthalpy of hydrogenation) can be measured.
THERMODYNAMIC EVIDENCE FOR STABILITYTHERMODYNAMIC EVIDENCE FOR STABILITY
2 3
MORE STABLE THAN EXPECTED
by 152 kJ mol-1
Experimental- 208 kJ mol-1- 120 kJ mol-1
Theoretical- 360 kJ mol-1
(3 x -120)
When cyclohexene (one C=C bond) is reduced to cyclohexane, 120kJ of energy is released per mole.
C6H10(l) + H2(g) ——> C6H12(l)
Theoretically, if benzene contained three separate C=C bonds it would release 360kJ per mole when reduced to cyclohexane
C6H6(l) + 3H2(g) ——> C6H12(l)
Actual benzene releases only 208kJ per mole when reduced, putting it lower down the energy scale
It is 152kJ per mole more stable than expected.This value is known as the RESONANCE ENERGY.
When unsaturated hydrocarbons are reduced to the corresponding saturated compound, energy is released. The amount of heat liberated per mole (enthalpy of hydrogenation) can be measured.
THERMODYNAMIC EVIDENCE FOR STABILITYTHERMODYNAMIC EVIDENCE FOR STABILITY
2 3
MORE STABLE THAN EXPECTED
by 152 kJ mol-1
Experimental- 208 kJ mol-1- 120 kJ mol-1
Theoretical- 360 kJ mol-1
(3 x -120)
When cyclohexene (one C=C bond) is reduced to cyclohexane, 120kJ of energy is released per mole.
C6H10(l) + H2(g) ——> C6H12(l)
Theoretically, if benzene contained three separate C=C bonds it would release 360kJ per mole when reduced to cyclohexane
C6H6(l) + 3H2(g) ——> C6H12(l)
Actual benzene releases only 208kJ per mole when reduced, putting it lower down the energy scale
It is 152kJ per mole more stable than expected.This value is known as the RESONANCE ENERGY.
When unsaturated hydrocarbons are reduced to the corresponding saturated compound, energy is released. The amount of heat liberated per mole (enthalpy of hydrogenation) can be measured.
HYBRIDISATION OF ORBITALS - HYBRIDISATION OF ORBITALS - REVISIONREVISION
The electronic configuration of a carbon atom is 1s22s22p2
1 1s
22s
2p
HYBRIDISATION OF ORBITALS - HYBRIDISATION OF ORBITALS - REVISIONREVISION
The electronic configuration of a carbon atom is 1s22s22p2
1 1s
22s
2p
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
22s
2p
The process is favourable because of the arrangement of electrons; four unpaired and with less repulsion is more
stable
HYBRIDISATION OF ORBITALS - HYBRIDISATION OF ORBITALS - REVISIONREVISION
The four orbitals (an s and three p’s) combine or HYBRIDISE to give four new orbitals. All four orbitals are equivalent.
2s22p2 2s12p3 4 x sp3
HYBRIDISE
sp3
HYBRIDISATION
HYBRIDISATION OF ORBITALS - HYBRIDISATION OF ORBITALS - REVISIONREVISION
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 2pHYBRIDISE
sp2
HYBRIDISATION
In ALKANES, the four sp3 orbitals repel each other into a tetrahedral arrangement.
In ALKENES, the three sp2 orbitals repel each other into a planar arrangement and the 2p orbital lies at right angles to them
STRUCTURE OF ALKENES - STRUCTURE OF ALKENES - REVISIONREVISION
Covalent bonds are formed by overlap of orbitals.
An sp2 orbital from each carbon overlaps to form a single C-C bond.
The resulting bond is called a SIGMA (δ) bond.
STRUCTURE OF ALKENES - STRUCTURE OF ALKENES - REVISIONREVISION
The two 2p orbitals also overlap. This forms a second bond; it is known as a PI (π) bond.
For maximum overlap and hence the strongest bond, the 2p orbitals are in line.
This gives rise to the planar arrangement around C=C bonds.
STRUCTURE OF ALKENES - STRUCTURE OF ALKENES - REVISIONREVISION
two sp2 orbitals overlap to form a sigma bond between the two carbon atoms
ORBITAL OVERLAP IN ETHENE - ORBITAL OVERLAP IN ETHENE - REVIEWREVIEW
two 2p orbitals overlap to form a pi bond between the two carbon atoms
s orbitals in hydrogen overlap with the sp2 orbitals in carbon to form C-H bonds
the resulting shape is planar with bond angles of 120º
STRUCTURE OF BENZENE - STRUCTURE OF BENZENE - DELOCALISATIONDELOCALISATION
The theory suggested that instead of three localised (in one position) double bonds, the six p () electrons making up those bonds were delocalised (not in any oneparticular position) around the ring by overlapping the p orbitals. There would be nodouble bonds and all bond lengths would be equal. It also gave a planar structure.
6 single bonds
STRUCTURE OF BENZENE - STRUCTURE OF BENZENE - DELOCALISATIONDELOCALISATION
6 single bonds one way to overlapadjacent p orbitals
The theory suggested that instead of three localised (in one position) double bonds, the six p () electrons making up those bonds were delocalised (not in any oneparticular position) around the ring by overlapping the p orbitals. There would be nodouble bonds and all bond lengths would be equal. It also gave a planar structure.
STRUCTURE OF BENZENE - STRUCTURE OF BENZENE - DELOCALISATIONDELOCALISATION
6 single bonds one way to overlapadjacent p orbitals
anotherpossibility
The theory suggested that instead of three localised (in one position) double bonds, the six p () electrons making up those bonds were delocalised (not in any oneparticular position) around the ring by overlapping the p orbitals. There would be nodouble bonds and all bond lengths would be equal. It also gave a planar structure.
STRUCTURE OF BENZENE - STRUCTURE OF BENZENE - DELOCALISATIONDELOCALISATION
6 single bonds one way to overlapadjacent p orbitals
delocalised piorbital system
anotherpossibility
The theory suggested that instead of three localised (in one position) double bonds, the six p () electrons making up those bonds were delocalised (not in any oneparticular position) around the ring by overlapping the p orbitals. There would be nodouble bonds and all bond lengths would be equal. It also gave a planar structure.
STRUCTURE OF BENZENE - STRUCTURE OF BENZENE - DELOCALISATIONDELOCALISATION
6 single bonds one way to overlapadjacent p orbitals
delocalised piorbital system
anotherpossibility
This final structure was particularly stable andresisted attempts to break it down through normalelectrophilic addition. However, substitution of anyhydrogen atoms would not affect the delocalisation.
The theory suggested that instead of three localised (in one position) double bonds, the six p () electrons making up those bonds were delocalised (not in any oneparticular position) around the ring by overlapping the p orbitals. There would be nodouble bonds and all bond lengths would be equal. It also gave a planar structure.
STRUCTURE OF BENZENESTRUCTURE OF BENZENE
STRUCTURE OF BENZENESTRUCTURE OF BENZENE
ANIMATIONANIMATION
WHY ELECTROPHILIC ATTACK?WHY ELECTROPHILIC ATTACK?
Theory The high electron density of the ring makes it open to attack by electrophiles
HOWEVER...
Because the mechanism involves an initial disruption to the ring,electrophiles will have to be more powerful than those which reactwith alkenes.
A fully delocalised ring is stable so will resist attack.
WHY SUBSTITUTION?WHY SUBSTITUTION?
Theory Addition to the ring would upset the delocalised electron system
Substitution of hydrogen atoms on the ring does not affect the delocalisation
Overall there is ELECTROPHILIC SUBSTITUTION
ELECTRONS ARE NOT DELOCALISEDAROUND THE WHOLE RING - LESS STABLE
STABLE DELOCALISED SYSTEM
ELECTROPHILIC SUBSTITUTIONELECTROPHILIC SUBSTITUTION
Theory The high electron density of the ring makes it open to attack by electrophiles
Addition to the ring would upset the delocalised electron system
Substitution of hydrogen atoms on the ring does not affect the delocalisation
Because the mechanism involves an initial disruption to the ring,
electrophiles must be more powerful than those which react with alkenes
Overall there is ELECTROPHILIC SUBSTITUTION
ELECTROPHILIC SUBSTITUTIONELECTROPHILIC SUBSTITUTION
Theory The high electron density of the ring makes it open to attack by electrophiles
Addition to the ring would upset the delocalised electron system
Substitution of hydrogen atoms on the ring does not affect the delocalisation
Because the mechanism involves an initial disruption to the ring,
electrophiles must be more powerful than those which react with alkenes
Overall there is ELECTROPHILIC SUBSTITUTION
Mechanism
• a pair of electrons leaves the delocalised system to form a bond to the electrophile
• this disrupts the stable delocalised system and forms an unstable intermediate
• to restore stability, the pair of electrons in the C-H bond moves back into the ring
• overall there is substitution of hydrogen ... ELECTROPHILIC SUBSTITUTION
ELECTROPHILIC SUBSTITUTION REACTIONS - ELECTROPHILIC SUBSTITUTION REACTIONS - NITRATIONNITRATION
Reagents conc. nitric acid and conc. sulphuric acid (catalyst)
Conditions reflux at 55°C
Equation C6H6 + HNO3 ———> C6H5NO2 + H2O
nitrobenzene
ELECTROPHILIC SUBSTITUTION REACTIONS - ELECTROPHILIC SUBSTITUTION REACTIONS - NITRATIONNITRATION
Reagents conc. nitric acid and conc. sulphuric acid (catalyst)
Conditions reflux at 55°C
Equation C6H6 + HNO3 ———> C6H5NO2 + H2O
nitrobenzene
Mechanism
ELECTROPHILIC SUBSTITUTION REACTIONS - ELECTROPHILIC SUBSTITUTION REACTIONS - NITRATIONNITRATION
Reagents conc. nitric acid and conc. sulphuric acid (catalyst)
Conditions reflux at 55°C
Equation C6H6 + HNO3 ———> C6H5NO2 + H2O
nitrobenzene
Mechanism
Electrophile NO2+ , nitronium ion or nitryl cation; it is generated in an acid-base reaction...
2H2SO4 + HNO3 2HSO4¯ + H3O+ + NO2+
acid base
ELECTROPHILIC SUBSTITUTION REACTIONS - ELECTROPHILIC SUBSTITUTION REACTIONS - NITRATIONNITRATION
Reagents conc. nitric acid and conc. sulphuric acid (catalyst)
Conditions reflux at 55°C
Equation C6H6 + HNO3 ———> C6H5NO2 + H2O
nitrobenzene
Mechanism
Electrophile NO2+ , nitronium ion or nitryl cation; it is generated in an acid-base reaction...
2H2SO4 + HNO3 2HSO4¯ + H3O+ + NO2+
acid base
Use The nitration of benzene is the first step in an historically important chain of reactions. These lead to the formation of dyes, and explosives.
ELECTROPHILIC SUBSTITUTION REACTIONS - ELECTROPHILIC SUBSTITUTION REACTIONS - HALOGENATIONHALOGENATION
Reagents chlorine and a halogen carrier (catalyst)
Conditions reflux in the presence of a halogen carrier (Fe, FeCl3, AlCl3)chlorine is non polar so is not a good electrophilethe halogen carrier is required to polarise the halogen
Equation C6H6 + Cl2 ———> C6H5Cl + HCl
Mechanism
Electrophile Cl+ it is generated as follows... Cl2 + FeCl3 FeCl4¯ + Cl+
a Lewis Acid
FRIEDEL-CRAFTS REACTIONS OF BENZENE - FRIEDEL-CRAFTS REACTIONS OF BENZENE - ALKYLATIONALKYLATION
Overview Alkylation involves substituting an alkyl (methyl, ethyl) group
Reagents a halogenoalkane (RX) and anhydrous aluminium chloride AlCl3
Conditions room temperature; dry inert solvent (ether)
Electrophile a carbocation ion R+ (e.g. CH3+)
Equation C6H6 + C2H5Cl ———> C6H5C2H5 + HCl
FRIEDEL-CRAFTS REACTIONS OF BENZENE - FRIEDEL-CRAFTS REACTIONS OF BENZENE - ALKYLATIONALKYLATION
Overview Alkylation involves substituting an alkyl (methyl, ethyl) group
Reagents a halogenoalkane (RX) and anhydrous aluminium chloride AlCl3
Conditions room temperature; dry inert solvent (ether)
Electrophile a carbocation ion R+ (e.g. CH3+)
Equation C6H6 + C2H5Cl ———> C6H5C2H5 + HCl
Mechanism
General A catalyst is used to increase the positive nature of the electrophile
and make it better at attacking benzene rings.AlCl3 acts as a Lewis Acid and helps break the C—Cl bond.
FRIEDEL-CRAFTS REACTIONS OF BENZENE - FRIEDEL-CRAFTS REACTIONS OF BENZENE - ALKYLATIONALKYLATION
Catalyst anhydrous aluminium chloride acts as the catalystthe Al in AlCl3 has only 6 electrons in its outer shell; a LEWIS
ACIDit increases the polarisation of the C-Cl bond in the haloalkanethis makes the charge on C more positive and the following
occurs
RCl + AlCl3 AlCl4¯ + R+
FRIEDEL-CRAFTS REACTIONS - FRIEDEL-CRAFTS REACTIONS - INDUSTRIALINDUSTRIAL ALKYLATIONALKYLATION
Industrial Alkenes are used instead of haloalkanes but an acid must be presentPhenylethane, C6H5C2H5 is made by this method
Reagents ethene, anhydrous AlCl3 , conc. HCl
Electrophile C2H5+ (an ethyl carbonium ion)
Equation C6H6 + C2H4 ———> C6H5C2H5 (ethyl benzene)
Mechanism the HCl reacts with the alkene to generate a carbonium ionelectrophilic substitution then takes place as the C2H5
+ attacks the ring
Use ethyl benzene is dehydrogenated to produce phenylethene (styrene);
this is used to make poly(phenylethene) - also known as polystyrene
FRIEDEL-CRAFTS REACTIONS OF BENZENE - FRIEDEL-CRAFTS REACTIONS OF BENZENE - ACYLATIONACYLATION
Overview Acylation involves substituting an acyl (methanoyl, ethanoyl) group
Reagents an acyl chloride (RCOX) and anhydrous aluminium chloride AlCl3
Conditions reflux 50°C; dry inert solvent (ether)
Electrophile RC+= O ( e.g. CH3C+O )
Equation C6H6 + CH3COCl ———> C6H5COCH3 + HCl
Mechanism
Product A carbonyl compound (aldehyde or ketone)
FURTHER SUBSTITUTION OF ARENESFURTHER SUBSTITUTION OF ARENES
Theory It is possible to substitute more than one functional group.
But, the functional group already on the ring affects...
• how easy it can be done • where the next substituent goes
Group ELECTRON DONATING ELECTRON WITHDRAWING
Example(s) OH, CH3 NO2
Electron density of ring Increases Decreases
Ease of substitution Easier Harder
Position of substitution 2,4,and 6 3 and 5
FURTHER SUBSTITUTION OF ARENESFURTHER SUBSTITUTION OF ARENES
Examples Substitution of nitrobenzene is...
• more difficult than with benzene
• produces a 1,3 disubstituted product
Substitution of methylbenzene is…
• easier than with benzene
• produces a mixture of 1,2 and 1,4 isomeric products
Some groups (OH) make substitution so mucheasier that multiple substitution takes place
STRUCTURAL ISOMERISMSTRUCTURAL ISOMERISM
1,3-DICHLOROBENZENEmeta dichlorobenzene
RELATIVE POSITIONS ON A BENZENE RING
1,2-DICHLOROBENZENEortho dichlorobenzene
1,4-DICHLOROBENZENEpara dichlorobenzene
Compounds have similar chemical properties but different physical properties
THE CHEMISTRYTHE CHEMISTRYOF ARENESOF ARENES
THE ENDTHE END
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