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Chapter 5 Dienes and Conjugated Systems5.1 Class and Nomenclature of Dienes5.2 Structure of Conjugated Dienes Molecular obitals5.3 Allylic Carbocations Hyperconjugation σ-p Hyperconjugation σ-πHyperconjugation5.4 Reaction of conjugated Dienes5.4.1 Electrophilic Attack on Conjugated Dienes: 1,4-addition Mechanism of conjugate addition
Kinetic versus thermodynamic control of reactions5.5 The Diels-Alde Cycloaddition Reaction
5.1 Classes and Nomenclature of DienesAn alkadiene
(二烯烃 ):
Hydrocarbon containing twocarbon-carbon double bonds
Alkadienes
Isolated dienes 1,4-pentadiene
1,5-Cyclo-octadiene
Separated by oneor more sp3-C atom.Separated by oneor more sp3-C atom.
Conjugated dienes:1,3-butadiene
1,3-cyclo- hexadiene
Double bonds andsingle bonds alternatealong the chain.
Double bonds andsingle bonds alternatealong the chain.
Cumulated dienes
Allene(丙二烯 )The C atom is commonfor two double bondsThe C atom is commonfor two double bonds
C C C C C
C C C C
H2C C CH2
Nomenclature:
cis,cis –2,4-hexadiene
(2Z,4Z)-2,4-hexadiene顺 ,顺 -2,4-己二烯(Z,Z)- 2,4-己二烯
(2Z,4E)-2,4-hexadiene
顺 ,反 -2,4-己二烯(Z,E)-
cis,trans-
P127.4.10P127.4.10• Suffix: ne diene• Cis-trans isomers:
C CC C
CH3H3C
H
HH
HC C
C CCH3
H3C
HH
H
H
CH
H
C CC
H
HH
H
5.2 Structure of Conjugated Dienes1,3-Butadiene:
4 C atoms are sp2-hybridized.
C2-C3 σbond: sp2-sp2overlap
πbond: 2p-2p overlapC2-C3 partially overlap
by 2p-2p orbital4 πelectrons are delocalized
over 4 C atomsDelocalization of πelectronslowers the energy.
4 C atoms are coplanar
P128P128
CH
H
C CC
H
HH
H
Two possible planar conformation of 1,3-butadiene:
s-Cis conformation s-Trans conformation
Antibonding molecularorbitals(反键轨道 )
The four p orbitals combine to form a set of πmolecularobitals:
Two of the πmolecular orbitals 1,3-butadiene are bonding molecular orbitals.
Bonding molecularorbitals(成键轨道 )
Ch. P94.Ch. P94.
En
ergy
π1
π2
π3*
π4*
(+)
(-)
(+)
(-) (+)
(-)
(+)
(+)
(+)
(-)
(-)
(-)
(-)(-)
(-)
(+)
(+)
(+)
CC C C
CC C C(-)
(-)(+)
(-) (+)
CC C C
CC C C
(+)
Molecular orbitals of 1,3-butadiene
node
π2 - HOMO (The highest occupied orbital)π3* - LUMO (the lowest unoccupied orbital)
π- πConjugate system:
The alternate system by single bond and double bond.
Character of conjugate system:πelectrons delocalization .
5.3 Allylic Carbocations
Relative Order of carbocation stability:
Allylic(烯丙型 )
> 3°> 2°> 1° >VinylAllyl(烯丙基 )
>
P129, 4.11P129, 4.11
Allyl cation (烯丙基正离子 )Allylic cation(烯丙基型正离子 )
H2C CH CH2 CH3CH CH CHCH3
CH3CH CH CHCH3 > C
C
C > H2C CH CH2
C
> C
H
C >
C
C
H
C >
H
CH2 CH3
C atom with positive chargeis sp2-hybridized. p orbital is vacant.
p -π overlap.
πelectrons delocalization
p -πconjugation
Resonance hybrid
CCC C
CCδ+
δ-
(CH3)2C CH CH2 (CH3)2C CH CH2
C C C
Hyperconjugation (超共轭效应 ) Ch.P96Ch.P96
σ-p Hyperconjugation:Obital overlap here
Vacant p orbital
sp2 hybride
The order of stability of carbocations:
C-H bond attached a positive carbon delocalize the positive charge
sp3 hybrideCR
H
H
CH2
H +C CR
H
H
H
σ-πHyperconjugationC-H bond atttached a Carbon-carbon double bond
Delocalization of electrons
Orbital overlap here
The stability of alkene is increasedby enhance of density of electronic cloud
CR
H
H
CH CH2
H
C CRH
CH
H
5.4 Reaction of conjugated Dienes5.4.1 Electrophilic Attack on Conjugated Dienes: 1,4-addition
1,3-butadiene
1-Bromo-2-butane (19%)
Mechanism of the addition:3-Bromo-1-butane (81%)
Step1. 1,2-addition
1,4-addition
The formation ofallylic carbocation
(烯丙基型正离子的生成 )
H2C CH CH CH2HBr H2C CH CH CH2
HBr
+-80 C°
CH2 CH CH CH2
Br H
Secondary allylic cation
(I) Primary Allylic cation (II)
Step 2. Cation-anion combination
Stability of allylic cations:(I) > (II)
1,4-addition
1,2-addition
H2C CH CH CH2HBr H2C CH CH CH3
H2C CH CH CH3 CH2 CH CH CH3
H2C CH CH CH2
HBr
CH2 CH CH CH2
Br H
H2C CH CH CH3 + Br δ+ δ+
Kinetic versus thermodynamic controlof reactions:
ΔG1,4 ΔG1,2
En
ergy
Reaction coordinate
Active energy:ΔG1,4 > ΔG1,2
Stability of product:1,2-addition < 1,4-addition
CH2 CH CH CH3
BrCH2 CH CH CH3 Br
H2C CH CH CH3
H2C CH CH + HBrBr
CH2
CH2
H2C CH CH CH3 + CH CH CH3
Br
Br
CH2H2C CH CH CH3 + CH CH CH3
Br
(44%) (56%)
40℃-80℃
r.t
(81%) (19%)
1,2-Addition product: Rate control or kineticcontrol product
1,4-Addition product:Equilibrium control or thermodynamiccontrol product
5.5 The Diels-Alder Cycloaddition Reaction
The conjugate addition of an alkene to diene
Otto Diels and Kurt Alder(Germany) receive the
1950 Nobel Prize in chemistry
Otto Diels and Kurt Alder(Germany) receive the
1950 Nobel Prize in chemistry
Diene Dienophile Adduct(双烯体 ) (亲双烯体 ) (加成物 )
Pericyclic reaction(周环反应 )
A B
X Y
BA
XY
Diels was the scientific mentor of Kurt Alder (see portrait) and together they discovered the reaction which bears their names, the Diels-Alder (DA) reaction. For this they jointly received the 1950 Nobel Prize in Chemistry. Diels was born in Hamburg, Germany into an academic family (his father was a professor of classical philology in Berlin, and two brothers alsobecame professors). He obtained the Ph.D. (1899)at the University of Berlin with the great Emil Fischer(see portrait), after which he was appointed to the faculty there. In 1907 his textbook "Einführung in die Organische Chemie“was published; it became one of the most popular texts in its field and,by 1962, had gone through 19 editions. In 1916 Diels became director of the Institute of Chemistry at the University of Kiel, where he remained until his retirement.Besides the DA reaction, Diels is also known for having discovered carbon suboxide (C3O2) and for his early research on the structure of cholesterol, especially for the use of selenium (rather than sulfur) for dehydrogenations, and for Diels' hydrocarbon (3'-methyl-1,2-cyclopentenophenanthrene) which he obtained from cholesterol by that technique.
Otto Paul Hermann Diels1876-1954
Alder is best known for his discovery, with Otto Diels (see portrait)of the cycloaddition reaction that bears their names, the Diels-Alder (DA) reaction.For this discovery they received the 1950 Nobel Prize in Chemistry.The reaction, which involves 1,4-addition of a dienophile(examples they studied included maleicanhydride,ethyl azodicarboxylate and benzoquinone)to a conjugated diene (their examples included cyclopentadiene, acyclic 1,3-dienes, furans and anthracene) is still one of the most general methods for constructing 6-membered rings.Born in Königshütte, Germany (now in Poland), Alder took his Ph.D. degree with Diels at theUniversity of Kiel in 1926. For a time he worked in industry on polymers and synthetic rubbers, then in 1940 joined the faculty of the University of Cologne where he remained until his untimely death after a brief illness, shortly before his 56th birthday. He co-authored 173papers which included, besides the stereochemistryand mechanism of the DA reaction, studies on the retro-DAreaction, the "ene" reaction, and applicationsto natural products synthesis. In 1955 Alder signed, with 17 other Nobel laureates, a declaration calling on nations to renounce war as a means of settling disputes.
Kurt Alder 1902-1958
1,3-Butadine Maleic anhydride adduct(100%)(马来酐 )
Maleic anhydride is used to identify conjugate Dienes.Characteristic of the Diels-Alder Reaction:
1. The reaction is reversible.2. Dienophile: with electron-withdrawing group
CH2
HC
HCCH2
HC
HC
C
C
O
O
O
benzene CHCH
C
C
O
O
O
+100 C°
H2C CH C
O
H H2C CH C
O
OCH2CH3 H2C CH C N
HC C COOCH3
3. Diene: with electron-releasing groups and s-cis conformation
3-Dimethyl-1,3-butadiene Adduct (100%)
not
4. Stereospecific: Syn-addition
cis- cis-
H3C
H3CH
OH3C
H3C
H
O
+30 C°
O
+H
H
COCH3
OCOCH3
O
COCH3
OCOCH3
H
H
CH3OOC
H+
CH3
H
Problem:
?
5. Application:a. Identification to conjugate dienes. b. Cyclization by the formation of C-C bond.
Problems to Chapter 5P1464.374.464.47
Additional problems:1.Electrophilic addition of Br2 to isoprene (异戊二烯 )yields the following product mixture:
H2C CCH CH2
CH3Br2 H2C CCHBrCH2Br +
CH3
BrH2C CBrCH CH2
CH3
(3%) (21%)
+ BrCH2C CHCH2Br
CH3
76%)
Of the 1,2-additionproducts, explain why3,4-dibromo-3-methyl-1-butene(21%) predominatesover 3,4-dibromo-1-butene(3%).
2. Draw the possible products resulting from addition of 1 equivalent of HCl to 1-phenyl- 1,3-butadiene. Which would you expect to predominate, and why?
3. How would you use Diels-alder reactions to prepare the following products? Show the starting diene, dienophilie in each case and the reactions.(1) (2)
CN
H
O
O