CH223 This lecture’s objectives: Welcome Objectivesncsu/CH223_fall_02/223fall12...This lecture’s...
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1 1 Welcome O O O H H O H OH CH223 Kay Sandberg, Ph.D. 2 Objectives This lecture’s objectives: ©Dr. Kay Sandberg 1) Review CH101, CH221 basic concepts 2) Introduce arenes & aromaticity 3 Domino effect ©Dr. Kay Sandberg Get started on the right foot! Strategy for success Understanding lecture work Understanding homework Understanding exams Understanding organic chemistry 4 ©Dr. Kay Sandberg Students who have an A daily average, but fail exams have not progressed past the “what”. Organic chemistry: What? Why? How? C students (at best) B students A students Fred 5 Energy consideration CH101 review Reactions: Understand species in nature tend to react to lower the system’s free energy: Sandberg’s analogy: E increasing E = increasing discomfort ©Dr. Kay Sandberg Higher E reactants Highest E transition state Lower E products relatively high energy species C C O Barney 6 The secret CH101 review Reactions: Understand Coulomb’s Law: Oppositely charged species are attracted to each other. ©Dr. Kay Sandberg Find the negative, find the positive, The SECRET!!!!! and let the negative “grab” the positive (and conversely, species of like charge are repelled.)
Transcript of CH223 This lecture’s objectives: Welcome Objectivesncsu/CH223_fall_02/223fall12...This lecture’s...
1
1
Welcome
O
O
OH
H
O
H
OH
CH223Kay Sandberg, Ph.D.
2
ObjectivesThis lecture’s objectives:
©Dr. Kay Sandberg
1) Review CH101, CH221 basic concepts2) Introduce arenes & aromaticity
3
Domino effect
©Dr. Kay Sandberg
Get started on the right foot!Strategy for success
Understanding lecture workUnderstanding homework
Understanding exams
Understanding organic chemistry
4
Will you make an A?
©Dr. Kay Sandberg
Students who have an A daily average, butfail exams have not progressed past the “what”.
Organic chemistry:
What?
Why?How?
C students (at best)
B studentsA students
Fred
5
Energy consideration
CH101 reviewReactions:
Understand species in nature tend to react to lower the system’s free energy:
Sandberg’s analogy:
E
increasing E = increasing discomfort
©Dr. Kay Sandberg
Higher Ereactants
Highest E transition state
Lower E products
relatively highenergy species
C C O Barney
6
The secret
CH101 reviewReactions:
Understand Coulomb’s Law:Oppositely charged species are attracted to each other.
©Dr. Kay Sandberg
Find the negative, find the positive,
The SECRET!!!!!
and let the negative “grab” the positive
(and conversely, species oflike charge are repelled.)
2
7
Terms
©Dr. Kay Sandberg
Secret of your success in CH223Find the negative charge carrierFind the positive charge carrier
neg (electrons) “grabs” pos
electrons are now the bond
Lewis base Lewis acide- pairdonor
e- pairacceptor
nucleophile electrophile
likeslikes
8
The secret in scientific terms
CH101 reviewReactions:
©Dr. Kay Sandberg
The SECRET!!!!!
Find the negative, find the positive,
and let the negative “grab” the positive
Find the nucleophile, find the electrophile,
and let the nucleophile bond w/ the electrophile
9
Electron flow arrows
C O
H
H
H
H
©Dr. Kay Sandberg
Wilma: A) Select the appropriate diagram.B) Select the electrophile.
H FC O
H
H
H
LP
F
σ bond
σ bond
LP
red blue
δ+ δ-Up or downin E?
10
ArenesH
H
H
H
H
H
© Kay Sandberg
Section 11.1Chapter 11: Arenes & Aromaticity
CH3
H
H
H
H
H
H
H
H
H
H
H
H
H
benzene toluene
naphthalene
11
Drugs
O
OH
© Kay Sandberg
F3C
OHN
H
aspirin
Prozac
N
OOCH3
O
O
H3C
cocaine
12
BiomoleculesO
O
H3N HHN
O
O
H3N HHO
CH3
H
O
HO
H
H
© Kay Sandberg
estrone
tryptophan
O
O
H3N H
phenylalanine
tyrosine
3
13
Aromatic vs aliphatic
© Kay Sandberg
Section 11.1Chapter 11: Arenes & Aromaticity
Conjugated Conjugatedcyclic
Special stability
Aromaticity
Aromatic HC Aliphatic HC
arenes14
Rxn comparison
© Kay SandbergSection 11.2
x,y-dibromo-a,b-hexadieneNo Rxn
Aromatic HC Aliphatic HC
Br2 CCl4Br2 CCl4
x,y-dibromocyclohexene
Br2 CCl4
15
Hydrogenation
© Kay Sandberg
Section 11.2
ExcessH2 Pd
16
Hydrogenation
© Kay Sandberg
Section 11.2
PdH2
17
Substitution
© Kay Sandberg
Section 11.2X
Y
Substitution productsare obtained readily
Aromatic ringis retained.
18
Hybridization in benzene C
CC
C
CC
H
H
H
H
H
HWhat is carbon’shybridization?
Betty
4
19
Bonding in benzene
© Kay Sandberg
Section 11.3Structural features of benzeneC6H6
120o
120o
120o
140 pm
sp2- sp2
single bond 146 pm
double bond 134 pm
6
54
3
21
1
2
6
5
4 3
20
Resonance in benzene
© Kay Sandberg
Section 11.5
6
54
3
21
43
21
6
5
Resonance6
54
3
21
Pebbles
21
Representations of toluene
© Kay Sandberg
Section 11.5
6
54
3
21
43
21
6
5
Resonance
It is common, however, for chemists to use one of the 2 resonance structures, but you should realize that reality is in between the 2 resonance structures.
toluene toluene
6 pi electronsare obvious
22
Bonding in conjugated aliphatic
Section 11.5
© Kay Sandberg
C CC
HH
H
HC
CC
CC
H
H
H
H
H
CH
CH
H
H
C CH
HH
Weaker πinteractions
Stronger πinteractions
Longer bonds
Shorter bonds
23
Bonding in aromatic
© Kay Sandberg
Section 11.5
Same length
Same strength πinteraction
No alternation24
Sigma & pi bonding in benzene
© Kay Sandberg
Section 11.7
6 pure 2p orbitals6 π electrons
Continuous π system
σ system
sp2 hybridized C
π system
C
CC
C
CC
H
H
H
H
H
H
5
25
Heats of hydrogentation
© Kay Sandberg
Section 11.6
E kJ
/mol 360
231 208
120
“
“
3 x 120H2 + 2 X 120 = 240
9 kJ conjugationstabilization
(3 x 120) – (2 x 9) = 342 kJ
3H2 +
2H2 +
Bam Bam
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Empirical resonance energy
© Kay Sandberg
Section 11.6Here we have 6 π-e’sthat are lower in Ethan 4 π-e’s
E kJ
/mol 360
231 208
152
120
“
“
3 x 120
Empiricalresonanceenergy
H2 +
3H2 +
2H2 +
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Stability of benzene
© Kay Sandberg
Section 11.6Stability of benzene
E kJ
/mol 360
231 208
152
120
“
“
3 x 120
Empiricalresonanceenergy
Hydrogenation:Rh or Pt, orhigher pressures,
higher temperatures.3H2 +
H2 +
2H2 +
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Stability of benzene
© Kay Sandberg
Section 11.6Stability of benzeneE
kJ/m
ol
337
129
208
Large stabilizationdue to π-e-’sbeing aromatic.
3 nonconjugateddoublebonds
360
23
Small stabilizationdue to π-e-’s beingconjugated, but notaromatic.
29
Solubitilty
© Kay Sandberg
Section 11.9
Physical properties of arenes•nonpolar•water insoluble•less dense than water
CCl4H2O
benzene 0.88
1.00
1.59
density (g/mL)
Dino
beforemixing
aftermixing 30
Nomenclature
© Kay Sandberg
Section 11.7Nomenclature of benzene & derivatives
bromobenzene
Br NO2
tert-butylbenzene
nitrobenzene
6
31
Special names
© Kay Sandberg
Section 11.7Nomenclature of benzene & derivatives
benzaldehyde
O
H
O
OH
benzoic acid
32
Special names
© Kay Sandberg
Section 11.7Nomenclature of benzene & derivatives
O
CH3OH
acetophenone phenol
When the benzene ring is a substituent it isnamed phenyl (C6H5-)
Rubble
33
Special names
© Kay Sandberg
Section 11.7Nomenclature of benzene & derivatives
anisole aniline
toluene
OCH3
NH2
CH3
styrene
George 34
Monosubstituted derivatives
1-phenylheptane
© Kay Sandberg
Section 11.7
butylbenzene
hexylbenzene
12
34
12
34
56
12
34
56
7
“benzene” = parent name
“phenyl” = branch name
heptylbenzene
Locantneeded
7 or morecarbons6 or less
carbons
Judy
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Monosubstituted derivatives
© Kay Sandberg
Write the IUPAC name.
Elroy
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Disubstituted derivatives
© Kay Sandberg
Section 11.7Nomenclature of benzene derivativesDisubstituted benzenes
Y
X X
Y
X
Yortho(1,2)
o-
meta(1,3)m-
para(1,4)
p-
12
34
5
61
3
2
45
61
4 3
2
5
6
7
37
o/m/p regioprefixes
© Kay Sandberg
Section 11.7Nomenclature of benzene & derivativesDimethyl derivatives: xylenes
o-xylene m-xylene p-xylene1,2-dimethylbenzene
1,3-dimethylbenzene1,4-dimethylbenzene
ortho meta para
CH3
CH3 CH3
CH3
CH3
CH3-xylene -xylene
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o/m/p regioprefixes
© Kay Sandberg
Section 11.7Nomenclature of benzene & derivativesDisubstituted benzenes
Y
X X
Y
X
Yortho meta para
X
o o
m mp
ipso
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o/m/p silly memory devices
© Kay Sandberg
Section 11.7Nomenclature of benzene & derivativesDisubstituted benzenes
ortho meta paraX
o o
m mp
YX
XY
X
Y
40
Practice
© Kay Sandberg
Section 11.7Nomenclature of benzene & derivativesDisubstituted benzenes
m-bromoisopropylbenzene
Br
Astro
meta-bromoisopropylbenzenealso acceptable
41
Trisubstituted derivativesNO2
Cl
O2N
© Kay SandbergSection 11.7
When parent is benzene, # to give the lowestlocant at the first point of difference (beforealphabetizing).
5
43
2
16 NO2
Cl
O2N1
65
4
32 NO2
Cl
O2N4
56
1
23 NO2
Cl
O2N
1-chloro-2,4-dinitrobenzene
1,3,4-trisubstituted 1,2,4-trisubstituted1,2,5-trisubstituted
o/m/p only used for disubstituted derivatives –cannot use for tri or higher substituion
Ignore di, tri, tetra, etc. when alphabetizing42
Numbering rule
© Kay Sandberg
Section 11.7Nomenclature of benzene derivatives
When parent is benzene, # to give the lowestlocant at the first point of difference (beforealphabetizing). (Highest priority rule)
When 2 differing numbering schemes are lowest,then use the one which gives the lowest locantto the branch listed first alphabetically.
1.
2.
8
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Practice with special namesCH3
NO2O2N
NO2
© Kay Sandberg
Section 11.7
F
OCH3
CH3CH2
Nomenclature of benzene derivatives
anisole
tolueneUnderstood C-1
Understood C-1
4-ethyl-2-fluoro
2,4,6-trinitro anilineUnderstood C-1
6
54
3
21
CH3
NO2O2N
NO2
NH2
CH3
CH2CH3
4
56
1
23 F
OCH3
CH3CH2
6
54
3
21
NH2
CH33
45
6
12
NH2
CH3
amino
toluene derivative? aniline derivative?
means no locant 1 in name 3-ethyl-2-methyl
Rosey
44
PrioritiesOH
© Kay Sandberg
Section 11.7Nomenclature of benzene derivatives
propan-1-ol
When the benzene ring is a substituent it isnamed phenyl (C6H5-)
3-phenyl
32
1OH
36
Use name to double checkcarbon #.
Alcohol has priority which means it isbonded to the parent.
Number from endwhich gives thehydroxy group the lower locant.
45
More practice
© Kay Sandberg
Section 11.7Which is (Z)-2-phenylbut-2-ene?
H3C
CH3
H
Hi
Lo
Hi
Lo
“zame zide”
Spacely
(Z)-(E)-
46
Benzyl vs phenyl
© Kay Sandberg
Section 11.7
Benzyl group (C6H5CH2-)
Br
benzyl bromide
Br
phenyl bromide
CBr
HH
methylene kink
ring is parentbromine branch
bromobenzene
ring is branchbromide is parent
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Benzyl vs allyl
© Kay Sandberg
Section 11.7
Br
benzyl bromide
benzylic Br
Br
Benzyl is analogous to allyl
allyl bromide
allylic Br
48
Benzylic vs allylic vs aryl
© Kay Sandberg
Section 11.12
C CC
CCC C
H
HBr
HH
Cl
H H
CC C
H
HBr
H
HCl
Vinylic H & Cl
Benzylic H & Br
“arylic”aryl H & Cl
Allylic H & Br
9
49
Aryl vs alkyl
© Kay Sandberg
Section 11.7Nomenclature of benzene & derivativesThe adjective “aryl” is analogous to “alkyl”.
aryl Calkyl C
H
aryl H
H
alkyl H
Cosmo 50
Reaction overview
2. Influence of aryl group as a substituenton the reactivity of another functional groupto which it is attached.
© Kay Sandberg
Section 11.10Reactions of arenes1. Ring as functional group.
Birch reductionElectrophilic aromatic substitution (EAS)
Benzyliccarbocation
Benzylicradical
alkenylbenzene
Nucleophilic aromatic substitution (NAS)
C C CC
51
Radical formation comparison
© Kay Sandberg
Section 11.12Free-radical halogenation of alkylbenzenes
CH
H
H
C
H
H
H
C HH3C
H3CCH3
CH
H
C
H
H
C
H3C
H3CCH3 H+
H+
H+
ΔHo
397 kJ/mol
368 kJ/mol
tert-butyl rad
allyl rad
52
Radical resonance delocalizsation
©Dr. Kay Sandberg
CC
CH
H
H
H
H
CC
CH
H
H
H
H
CC
CH
H
H
H
H
δ.δ.
i.e., Resonance delocalization
53
Benzyl radical formation
© Kay Sandberg
Section 11.12Free-radical halogenation of alkylbenzenes
CH
H
H
C
H
H
H
C HH3C
H3CCH3
CH
H
C
H
H
C
H3C
H3CCH3 H+
H+
H+
ΔHo
397 kJ/mol
368 kJ/mol
356 kJ/mol
tert-butyl rad
allyl rad
benzyl rad 54
Resonance structures
© Kay Sandberg
Section 11.12Stability of benzyl radical
3 2
1
65
4 CH
H
3 2
1
65
4 CH
H
3 2
1
65
4 CH
H
3 2
1
65
4 CH
H
Resonance delocalized:
Jane
10
55
Resonance structures
© Kay SandbergSection 11.12
3 2
1
65
4 CH
H
3 2
1
65
4 CH
H
3 2
1
65
4 CH
H
3 2
1
65
4 CH
H
Notice where the rad is not!
Tom 56
Radical stability chart
© Kay Sandberg
Section 10.3
EC C
CH
H
H
H
H
RC
RR
RC
RH
RC
HH
HC
HH
C HCH2 vinyl radical (least stable)
allyl radical
radical stabilitiesradical stabilities
C CC
HH
C
H
CCC
H
HH
H
benzyl radical (most stable)
57
Radical orbital picture
© Kay Sandberg
Section 11.12Stabilization due to overlap of benzylic pure p orbitalwith the extended π system of ring
Benzyl radical
58
Benzylic vs aryl H abstration
© Kay Sandberg
Section 11.12Regioselectivity of H abstraction
HH
Abstraction of aryl HAbstraction of benzylic H
radical ⊥ to π system less stable
sp3p
59
Radical stability chart
© Kay Sandberg
Section 10.3
EC C
CH
H
H
H
H
RC
RR
RC
RH
RC
HH
HC
HH
CH H2C vinyl radical (least stable)
allyl radical
radical stabilitiesradical stabilities
C CC
HH
C
H
CCC
H
HH
H
benzyl radical (most stable)60
Benzylic vs aryl radical
© Kay Sandberg
Section 11.12Regioselectivity of H abstraction
HH
Abstraction of aryl HAbstraction of benzylic H
benzylic vinylic (“arylic”)
11
61
Free radical halogenation step 1
© Kay Sandberg
Section 11.12Regioselectivity of free-radical halogenation
Cl Cl Cl + Cl
hν
The homolytic cleavage of the Cl-Cl bond to create the atomic chlorine atoms.
62
Step 2
C
H
H
H Cl+
Section 11.12Free radicals: alkylbenzene
Step 1 initiation
Cl Cl C l + Cl
hν
Step 2 propagation
CH
HH Cl+
H atom abstraction from toluene by Cl atom generating benzyl radical
© Kay Sandberg
benzyl radical
63
Step 3
Section 11.12Free radicals: alkylbenzene
Step 1 initiation
Cl Cl C l + Cl
hν
C
H
H
H Cl+
Step 2 propagation
C
H
H
H Cl+
Chain propagation
C
H
H
Cl Cl+ C
H
H
Cl Cl+
Benzyl • reacts with molecular Cl creating atomic Cl ...© Kay Sandberg
64
Benzylic chlorination
Section 11.12Free radicals: alkylbenzene
CH H
H
light
CH Cl
H
Cl2
toluene
© Kay Sandberg
Cl2
light
CH Cl
Cl
Cl2
light
CCl Cl
Cl
benzyl chloride
(dichloromethyl)benzene
(trichloromethyl)benzene
65
Benzylic bromination
Section 11.12Free radicals: alkylbenzene
CH H
H
light
CH Br
H
NO2 NO2
Br2+CCl4, 80oC
© Kay Sandberg
p-nitrotoluene p-nitrobenzyl bromide
+ HBr
66
NBS benzylic bromination
© Kay Sandberg
ethylbenzene 1-bromo-1-phenylethane
CBr C
H
H
H
HH
H
H
H
H
NH
O
O
+NBS
Section 11.12Free radicals: alkylbenzene
CH C
H
+CCl4, 80oC
H
H
HH
H
H
H
H
NBr
O
O
peroxide
12
67
NBS benzylic brominationO
CH
H
HH
H
C
NO2
H
HBr
H
Section 11.12
OC
+CCl4, 80oC
H
H
HH
H
C
NO2
H
NBr
O
O
peroxide
HH
H
© Kay Sandberg
NH
O
O
+
O
NO2
Br
OC
+CCl4, 80oC
H
H
HH
H
C
NO2
H
NBr
O
O
peroxide
HH
H
Jerry
