explain why benzene less reactive towards electrophiles than alkenes
each benzene C sp2 hybridised >
each C use 2 sp2 orbitals form 2 σ bonds w/ 2 other C atoms(head-on overlap) >
remaining sp2 form σ bond w/ 1s orbital of H >
each C unhybridised p overlap sideways w/ 2 adjacent p orbitals >
forms 2 continuous e- clouds -> π e- cloud
delocalised π e- cloud confers extra stability >
generally unreactive to electrophiles >
catalyst required to generate stronger electrophile(full +ve charge)
why benzene preferably undergoes substitution than addition like alkene?
each benzene C sp2 hybridised >
each C use 2 sp2 orbitals form 2 σ bonds w/ 2 other C atoms(head-on overlap) >
remaining sp2 form σ bond w/ 1s orbital of H >
each C unhybridised p overlap sideways w/ 2 adjacent p orbitals >
forms 2 continuous e- clouds -> π e- cloud
delocalised π e- cloud confers extra stability >
addition makes C sp3 hybridised, lose π e- system >
to preserve stability, undergoes substitution
benzene react w/ X2
Electrophilic substitution
r&c: X2, anhydrous AlX3/FeX3, heat
G; X2 + AlX3/FeX3 -> X+ + AlX4-/FeX4-
R; HX formed, AlX3/FeX3 regenerated
catalyst anhydrous; if (aq), will hydrolyse in H2O, catalyst destroyed
what is purpose of Lewis acid in electrophilic substitution?
accept lp of e- from X2 >
form stronger electrophile X+
benzene react w/ conc HNO3
Electrophilic substitution
r&c: conc HNO3, conc H2SO4, 50oC
mono-nitration @ 50oC, further subn > temp
G; HNO3 + H2SO4 -> NO2+ + HSO4- + H2O
F; arrow directed to N, where +ve charge is
what is purpose of H2SO4 in nitration of benzene?
acts as Bronsted-Lowry acid >
protonate HNO3 >
generate stronger electrophile NO2+
benzene react w/ RX
Electrophilic substitution(Friedel-Crafts Alkylation)
r&c: RX, anhydrous AlX3, heat
higher temp, favour polysubbed pdt
G; RX + AlX3 -> R+ + AlX4-
F; arrow directed to C, where +ve charge is
R; HX formed
what is purpose of Lewis acids in Friedel-Crafts alkylation?
act as Lewis acid >
accept e- pair from RX >
generate stronger electrophile R+
describe electrophilic substitution
GFR, Green Fucking Ranger
Generate stronger electrophile
rxt + catalyst -> electrophile + reacted catalyst
Form arenium cation
benzene + electrophile -> arenium ion
*slow, + within ring, ring cut @ area where sp2 orbital lost, -ve e- cloud attacks electrophile(arrow)
Restore aromaticity, Regenerate catalyst
arenium ion + reacted catalyst -> pdt + catalyst
*fast, to restore aromaticity, e- donated from H to ring(arrow), catalyst regenerated
alkyl side-chain of benzene react w/ X2
FRS
r&c: limited X2(g), UV light
alkyl side-chain of benzene react w/ oxidising agents
Oxidation
r&c: KMnO4(aq), H2SO4(aq), heat
alkylbenzene + 3[O] -> benzoic acid + H2O
obs: purple KMnO4 decolourises, white
OR
r&c: KMnO4(aq), NaOH(aq), heat
alkylbenzene + 3[O] -> sodium benzoate + 2H2O
obs: purple KMnO4 turns green then forms brown ppt
when will halogenation occur in the side–chain or aromatic nucleus in arenes?
FRS; side-chain when limited X2(g), UV light
electrophilic substitution; aromatic nucleus when X2(g), anhydrous FeX3/AlX3, heat
what is position of substitution in electrophilic substitution of mono-substituted arenes?
EDG(2,4 directing) - ring-activating, donate e- to π e- cloud >
↑ e- density in ring >
benzene ring > e--rich, > reactive to electrophilic attack >
requires milder conditions, i.e.
mono-nitration of EDG-mono-subbed arenes, requires temp <30oC
EWG(1,3 directing) - ring-deactivating, take e- away from π e- cloud >
↓ e- density in ring >
benzene ring < e--rich, < reactive to electrophilic attack >
requires harsher conditions, i.e.
mono-nitration of EWG-mono-subbed arenes, requires temp >50oC
what are the environmental consequences of CO, oxides of nitrogen, unburnt hydrocarbons formed from engine combustion and their catalytic removal?
CO; prevents transport of O2 around body
NO, NO2; acidic gas, forms acid rain causing corrosion,causes respiratory problems in humans, interfere w/ plant metabolism, in strong sunlight forms photochemical fog causing lung damage
N2O; enhanced greenhouse effect
SO2, SO3; acidic gas, forms acid rain causing corrosion
unburnt hydrocarbons; in strong sunlight forms photochemical smog causing lung damage, enhanced greenhouse effect
what are the environmental consequences of gases that contribute to the Greenhouse effect?
Greenhouse gases trap infrared radiation from earth's surface >
trap heat in atmosphere, increases temp >
deforestation, burning of fossil fuels lead to enhanced greenhouse effect, result in global warming >
melts ice caps, rising sea levels; affects wildlife, environment
what is petroleum, and what is the importance of recycling?
fossil fuel; formed when dead organisms buried underground subjected to high temp, pressure >
takes millions of years to form, consumed faster than replaced >
hence finite, non-renewable resource
thus, recycling of plastic important;
plastic require large quantities of non-renewable fossil fuels >
non-biodegradable, takes up scarce land spaces(landfills), incineration releases toxic gases >
recycling reuses plastic waste as feedstock for new plastic products >
lowers environmental impact
benzene react w/ RCOCl
Electrophilic substitution(Friedel-Crafts Acylation)
r&c: RCOCl, anhydrous AlCl3, heat
G; RCOCl + AlCl3 -> RCO+ + AlCl4-
R; HCl formed
identify alkylbenzene
test: add few drops of KMnO4(aq), H2SO4(aq) to each sample separately, heat
obs: purple KMnO4 decolourises, white ppt of benzoic acid formed upon cooling
NaOH(aq) used; purple KMnO4 turns green, then brown ppt forms
differentiate alkylbenzene & methylbenzene
test: add few drops of KMnO4(aq), H2SO4(aq) to each sample separately, heat;
pass any gas evolved thru limewater.
obs: for both, purple KMnO4 decolourises, white ppt of benzoic acid formed upon cooling;
ethylbenzene; CO2 gas evolved forms white ppt w/ limewater