Created byProfessor William Tam & Dr. Phillis

Chang Ch. 8 - 1

Chapter 8

Alkenes and Alkynes II:Addition Reactions

Ch. 8 - 2

About The Authors

These PowerPoint Lecture Slides were created and prepared by Professor William Tam and his wife, Dr. Phillis Chang.

Professor William Tam received his B.Sc. at the University of Hong Kong in 1990 and his Ph.D. at the University of Toronto (Canada) in 1995. He was an NSERC postdoctoral fellow at the Imperial College (UK) and at Harvard University (USA). He joined the Department of Chemistry at the University of Guelph (Ontario, Canada) in 1998 and is currently a Full Professor and Associate Chair in the department. Professor Tam has received several awards in research and teaching, and according to Essential Science Indicators, he is currently ranked as the Top 1% most cited Chemists worldwide. He has published four books and over 80 scientific papers in top international journals such as J. Am. Chem. Soc., Angew. Chem., Org. Lett., and J. Org. Chem.

Dr. Phillis Chang received her B.Sc. at New York University (USA) in 1994, her M.Sc. and Ph.D. in 1997 and 2001 at the University of Guelph (Canada). She lives in Guelph with her husband, William, and their son, Matthew.

Ch. 8 - 3

C C E Nu

E

C C

Nu

+

1. Addition Reactions of Alkenes

Ch. 8 - 4

1A.How To Understand Additions

to Alkenes This is an addition reaction: E–Nu added across the double bond

C C E Nu

E

C C

Nu

+

Bonds broken Bonds formed

p-bond s-bond 2 s-bonds

Ch. 8 - 5

Since p bonds are formed from the overlapping of p orbitals, p electron clouds are above and below the plane of the double bond

C Cp electron clouds

Ch. 8 - 6

Electrophilic●electron seeking●C=C and C≡C p bonds are

particularly susceptible to electrophilic reagents (electrophiles)

Common electrophile●H+, X+ (X = Cl, Br, I), Hg2+, etc.

Ch. 8 - 7

In an electrophilic addition, the p electrons seek an electrophile, breaking the p bond, forming a s bond and leaving a positive charge on the vacant p orbital on the adjacent carbon. Addition of B– to form a s bond provides an addition product

Ch. 8 - 8

C CE Nu

C C

E

+ Nu

Nu

C C

E

Ch. 8 - 9

C C

A

CC

E

CC

NuNuE Nu

2. Electrophilic Addition ofHydrogen Halides to Alkenes: Mechanism and Markovnikov’sRule

Mechanism

Ch. 8 - 10

C C

E

Mechanism●Sometimes do not go through a

“free carbocation”, may go via

Ch. 8 - 11

C C

H

H

H

HE Nu

E

CC H

H

H

H

E

C CH

H

H

H

E

C CH

H

H

H

Nu E

CC H

H

H

H

Nu

Nu

same as

same as

Markovnikov’s Rule ●For symmetrical substrates, no

problem for regiochemistry

Ch. 8 - 12

E NuC C

H

H3C

H

H E

CC H

H

CH3

H

E

C CCH3

H

H

H

E

C CCH3

H

H

H

Nu E

CC H

H

CH3

H

Nu

Nu Nu

or

different from

Markovnikov’s Rule ●But for unsymmetrical

substrates, two regioisomers are possible

Ch. 8 - 13

Markovnikov’s Rule ●In the electrophilic addition of

an unsymmetrical electrophile across a double bond of an alkene, the more highly substituted and more stabilized carbocation is formed as the intermediate in preference to the less highly substituted and less stable one

Ch. 8 - 14

E NuE Nu E

Markovnikov’s Rule ●Thus

E

NOT

Note: carbocation stability 3o > 2o > 1o

Ch. 8 - 15

BrBr

fast

Addition of Hydrogen Halides●Addition of HCl, HBr and HI

across a C=C bond●H+ is the electrophile

slow

r.d.s

H Br+

Br

NO

Ch. 8 - 16

Ch. 8 - 17

2A.Theoretical Explanation ofMarkovnikov’s Rule

H XC C

H

H3C

H

H

H

CC H

H

CH3

H

H

C CCH3

H

H

H

or

2o carbocation

(more stable)

1o carbocation

(more stable)

step 1(slowr.d.s.)

One way to state Markovnikov’s rule is to say that in the addition of HX to an alkene, the hydrogen atom adds to the carbon atom of the double bond that already has the greater number of hydrogen atoms

Ch. 8 - 18

H Br

H H

Br

Br

fast(1o cation)(minor)

slow(r.d.s.)

Br

fast

H

Br

H

(2o cation)

(major)

☓

Step 1 Step 2

Ch. 8 - 19

Ch. 8 - 20

Examples

+(1)H Cl

Cl

H

H

Cl

(95 : 5)

+(2)H Br

(98 : 2)

H

Br

Br

H

Ch. 8 - 21

2B.Modern Statement of Markovnikov’s Rule

In the ionic addition of an unsymmetrical reagent to a double bond, the positive portion of the added reagent attaches itself to a carbon atom of the double bond so as to yield the more stable carbocation as an intermediate

Ch. 8 - 22

Examples

(1)Cl OH

Cl

OH

Cl

OH

(major)more stable

3o cation

Cl Cl

OH

OH

(minor)less stable

1o cation

Ch. 8 - 23

Examples

(2)I Cl

Cl

(major)more stable

3o cation

I I

Cl

(minor)less stable

1o cation

ClCl

II

Ch. 8 - 24

2C. Regioselective Reactions When a reaction that can potentially

yield two or more constitutional isomers actually produces only one (or a predominance of one), the reaction is said to be regioselective

+H Cl

Cl

H

H

Cl

95 : 5

(major) (minor)

Regioselectivity:

regioisomers

Ch. 8 - 25

2D. An Exception to Markovnikov’s Rule

Via a radical mechanism (see Chapter 10)

This anti-Markovnikov addition does not take place with HI, HCl, and HF, even when peroxides are present

H Br Br(anti-Markovnikov'sproduct)RO OR

heat H

Ch. 8 - 26

C C

H

H

Bu

HH X

3. Stereochemistry of the IonicAddition to an Alkene

C CH2 HH

Bu

X

X

achiraltrigonal planar

carbocation

C CH3H

X

Bu(S)-2-Halohexane

(50%)

C CH3

H

X

Bu

(R)-2-Halohexane(50%)

attack from top

attack from bottom

race

mate

Ch. 8 - 27

4. Addition of Sulfuric Acid to Alkenes

conc. H2SO4

cold

OSO3H

H

HOS

O

HO

O

H

OSO3H

Addition of H–OSO3H across a C=C bond

Hmore stable3o cation

less stable1o cation

Ch. 8 - 28

4A.Alcohols from Alkyl HydrogenSulfates

The overall result of the addition of sulfuric acid to an alkene followed by hydrolysis is the Markovnikov addition of H– and –OH

conc. H2SO4

cold

OSO3H

H

OH

H

H2O

heat

Ch. 8 - 29

5. Addition of Water to Alkenes:Acid-Catalyzed Hydration

Overall process●Addition of H–OH across a C=C

bond●H+ is the electrophile●Follow Markovnikov’s rule

OH HH2O

dilute H3O+

(e.g. dilute H2SO4, H3PO4)

Ch. 8 - 30

H O

H

H

more stable

3o cation

slow

(step 1)

H

H2O

fast

(step 2)

H

OH H

H2Ofast(step 3)

H

OH

+H O

H

H

5A.Mechanism

Ch. 8 - 31

5B.Rearrangements Rearrangement can occur with certain

carbocations

H2O

H2SO4H

1,2-alkyl shift

H2OOH

(major product)

OH

NOT

Ch. 8 - 32

6. Alcohols from Alkenes throughOxymercuration–Demercuration:Markovnikov Addition

Step 1: Oxymercuration

C C

HO HgOAc

C CHg(OAc)2

THF-H2O

Step 2: Demercuration

C C

HO HgOAc

NaBH4

OHC C

HO H

Ch. 8 - 33

6A.Regioselectivity of Oxymercura-tion–Demercuration Oxymercuration–demercuration is

also highly regioselective and follows Markovnikov’s rule

HO

HgOAcHg(OAc)2

THF-H2O

NaBH4

OH

HO

H

Ch. 8 - 34

6B.Rearrangements Seldom Occur inOxymercuration–Demercuration Recall: acid-catalyzed hydration of

some alkenes leads to rearrangement products

H2O

H2SO4

OH

H

e.g.

Ch. 8 - 35

O

H

H H

H

1,2-alkyl shift

HH2O

OH

H

H2O

H2O

H2SO4

Ch. 8 - 36

Rearrangements of the carbon skeleton seldom occur in oxymercuration–demercuration

H

OH

1. Hg(OAc)2, THF-H2O

2. NaBH4

Hg(OAc)

OHvia

no rearrangement

Ch. 8 - 37

HgOAc

+AcO

HO

HgOAc

O

HgOAc

HH

6C. Mechanism of Oxymercuration Does not undergo a “free

carbocation”

OAc

Hg

OAc

H2O

H2O

Ch. 8 - 38

H3C H

H3CHg(OAc)

Hg(OAc)2

THF-H2O

Stereochemistry●Usually anti-addition

H2O

OH

CH3

H

Hg(OAc)

Ch. 8 - 39

Although attack by water on the bridged mercurinium ion leads to anti addition of the hydroxyl and mercury groups, the reaction that replaces mercury with hydrogen is not stereocontrolled (it likely involves radicals). This step scrambles the overall stereochemistry

The net result of oxymercuration–demercuration is a mixture of syn and anti addition of –H and –OH to the alkene

Ch. 8 - 40

Solvomercuration-Demercuration

OR

Hg(O2CCF3)

NaBH4

OH

OR

H

Hg(O2CCF3)2

THF-ROH

Ch. 8 - 41

7. Alcohols from Alkenes throughHydroboration–Oxidation:Anti-Markovnikov Syn Hydration

Addition of H–BH2 across a C=C bond

C C C C

H BH2

"BH3"

Ch. 8 - 42

BH3 exists as dimer B2H6 or complex with coordinative solvent

B B

H

H

H H

H

H

OB

H

H

H

Me

S

Me

B

H

H

H

(BH3-THF) (BH3-DMS)

Ch. 8 - 43

H3C H

1. BH3-THF

2. H2O2, OH

H

CH3

OH

H

syn addition

Anti-Markovnikov additionof “H” & “OH”

Ch. 8 - 44

H3C H

Hg(OAc)2

THF-H2O

OH

CH3

H

Hg(OAc)

NaBH4

OH

CH3

H

H

anti addition

Markovnikov additionof “H” & “OH”

Compare with oxymercuration-demercuration

Ch. 8 - 45

8. Hydroboration: Synthesis ofAlkylboranes

C Chydroboration

C C

BH

H B+

alkene boronhydride

alkylborane

Ch. 8 - 46

8A.Mechanism of Hydroboration

H

H3C

H

H

+

H BH

H

H

H3C

H

H

H BH

H

complex

H

H3C

H

H

H BH

H

HH3C

HH

H B

HH

four-atomconcerted T.S.

HH3C

HH

H B

H

H

syn additionof H and B

Ch. 8 - 47

Other examples

(1)H BH2-THF

H BH2 H2B H

+

(99 : 1)

(2)H BH2-THF

H BH2 H2B H

+

(98 : 2)

Ch. 8 - 48

8B.Stereochemistry of Hydroboration

Syn addition

H3C HBH3-THF

H

CH3

BH2

H

Ch. 8 - 49

9. Oxidation and Hydrolysis ofAlkylboranes

H B

(trialkyl borane)

H B

H

H

H BH2

BH

B

H

B always endsup on the leasthindered carbon

Ch. 8 - 50

Oxidation

BH2O2

O

BO O

Ch. 8 - 51

●Via

R3B O OH

R

B

R

R O OHR

BOR

R

O OH

ROB

OR

ROHO

R

B

OR

O OR

HORO

BOR

OR

R

B

O

R OR

OH

Ch. 8 - 52

Hydrolysis

NaOHH2O

O

BO O

OH + Na3BO33

Ch. 8 - 53

Overall synthetic process of hydroboration-oxidation-hydrolysis

OHH

1. BH3-THF

2. H2O23. NaOH, H2O

●Overall: anti-Markovnikov addition of H–OH across a C=C bond

●Opposite regioisomers as oxymercuration-demercuration

Ch. 8 - 54

Example

H3C H

BH3-THFH

CH3

BH2

H

H2O2

OHH

CH3

OH

H

anti-Markovnikovsyn addition

This oxidation step occurs with retention of configuration

Ch. 8 - 55

10.Summary of Alkene HydrationMethods

Summary of Methods for Converting Alkene to Alcohol

ReactionRegiochemistr

yStereochemistr

y

Occurrence of Rearrangemen

ts

Acid-catalyzed hydration

Markovnikov addition

Not controlled Frequent

Oxymercuration-demercuration

Markovnikov addition

Not controlled Seldom

Hydroboration-oxidation

Anti-Markovnikov addition

Stereospecific: syn addition ofH – and –OH

Seldom

Ch. 8 - 56

Examples

H

H2OH

OH

1. Hg(OAc)2, THF-H2O

2. NaBH4, OHH

OH

1. BH3-THF

2. H2O2, OHOH

H

with rearrangement

Markovnikov addition of H2O without rearrangement

anti-Markovni-kov, syn addition of H2O

H

Hvia1,2-hydride

shift

Ch. 8 - 57

11.Protonolysis of Alkylboranes

R B R H CH3CO2 B+heat

CH3CO2H

alkylborane alkane

Protonolysis of an alkylborane takes place with retention of configuration; hydrogen replaces boron where it stands in the alkylborane

Overall stereochemistry of hydroboration–protonolysis: syn

Ch. 8 - 58

e.g.

H3C H H D

HH3C1. BH3-THF

2. CH3CO2D

+ enantiomer

H BH2

HH3C

via

Ch. 8 - 59

12. Electrophilic Addition of Bromine and Chlorine to Alkenes

Addition of X–X (X = Cl, Br) across a C=C bond

Br2C C

Br

C C

BrCCl4

(vicinaldibromide)

Ch. 8 - 60

Examples

(anti addition of Br2)

Br

Br

Br

Br

+Br2

5oC

(racemate)

(1)

(anti addition of Cl2)

Cl2

10oC(2) Ph

PhPh

Ph

Cl

Cl

Cl

PhPh

Cl

same as

(rotation of C1-C2 bond)

1

2

Ch. 8 - 61

Br

+ Br

C C

Br

Br

12A. Mechanism of Halogen Addition

C C + Br Br

Br

Br

Br–Br bond becomes polarized when close to alkene

(vincinalDibromid

e)(bromoniu

m)

Ch. 8 - 62

Br

Br

H H CCl4

Br Br

Stereochemistry●Anti addition

H

Br

Br

H

SN2 reaction

(anti)

enantiomer +

Ch. 8 - 63

13. Stereospecific Reactions

A reaction is stereospecific when a particular stereoisomeric form of the starting material reacts by a mechanism that gives a specific stereoisomeric form of the product

Ch. 8 - 64

●Reaction 1

Br2

H3C

H

H

CH3 Br

CHH3C

C

CH3

Br

H

CCl4

trans-2-Butene

H3C

BrBr

CH3

H H

(2R,3S)-2,3-Dibromobutane(a meso compound)

●Reaction 2Br2

H3C

H

CH3

H Br

CHH3C

C

H

Br

CH3

CCl4

cis-2-Butene (2R,3R)

Br

C HCH3

C

H

Br

H3C

(2S,3S)

+

(a pair of enantiomers)

Ch. 8 - 65

C CH3CH

CH3

H

Br

bromoniumion

(achiral)

Addition of bromine to cis-2-Butene

C CH3C

H

CH3

H

Br

Br

Br

CHH3C

C

H

Br

CH3

(2R,3R)-2,3-Dibromobutane(chiral)

(a)

Br

C HCH3

C

H

Br

H3C

(2S,3S)-2,3-Dibromobutane(chiral)

(b)

Br(a) (b)

Ch. 8 - 66

C CH3CH

HCH3

Br

bromoniumion

(achiral)

Addition of bromine to trans-2-Butene

C CH3C

H

H

CH3

Br

Br

Br

CHH3C

C

CH3

Br

H

(R,S)-2,3-Dibromobutane(meso)

(a)

Br

C CH3H

C

H

Br

H3C

(R,S)-2,3-Dibromobutane(meso)

(b)

Br(a) (b)

Ch. 8 - 67

14. Halohydrin Formation

Addition of –OH and –X (X = Cl, Br) across a C=C bond

X+ is the electrophile Follow Markovnikov’s rule

X2C C

OH

C C

XH2O

Ch. 8 - 68

H3C HH2O

Br Br

BrH3C H

H3CBr

H2O

OH

CH3

H

Br

Mechanism

Ch. 8 - 69

OMe

Br

Br2

MeOH

e.g.

Other variation●If H2O is replaced by ROH, RÖH

will be the nucleophile

Ch. 8 - 70

15.Divalent Carbon Compounds:Carbenes

15A. Structure and Reactions of Methylene

CH2 N N CH2 + N Nheat

or light

Diazomethane Methylene(a carbene)

Nitrogen

Ch. 8 - 71

CH2 N N

I

N NH2C CH2 N N

II III

C C CH2+ CC

CH H

Alkene Methylene Cyclopropane

Ch. 8 - 72

15B. Reactions of Other Carbenes: Dihalocarbenes

CCl2

H

CCl

ClCl

OtBuCl+ tBuOH +

:CX2 (e.g. :CCl2) Generation by a-elimination of

chloroform

Ch. 8 - 73

H

H

Cl

Cl

(a cyclopropane)

tBuOK

CHCl3

Usually a syn (cis) addition across a C=C bond

Ch. 8 - 74

ClCl

ClCl

CCl2

CCl2

Stereospecific reactions

Ch. 8 - 75

15C. Carbenoids: The Simmons-Smith Cyclopropane Synthesis

CH2I2 Zn(Cu)+

(Zinc-coppercouple)

(a carbenoid)

ICH2

ZnI

Ch. 8 - 76

A stereospecific syn (cis) addition across a C=C bond

CH2I2

Zn(Cu)(trans) (trans)

CH2I2

Zn(Cu)

(cis) (cis)

Ch. 8 - 77

16.Oxidation of Alkenes:Syn 1,2-Dihydroxylation

Overall: addition of 2 OH groups across a C=C bond

Reagents: dilute KMnO4 / OH⊖ / H2O / cold or OsO4, pyridine then NaHSO3, H2O

C C

OH OH

Ch. 8 - 78

16A. Mechanism for Syn Dihydroxylation of Alkenes

C C

dil. KMnO4

OH , H2O

cold

C C

O O

MnOO

OH

H2OC C

OH OH

+ MnO2

C C

O O

OsO O

NaHSO3

H2OC C

OH OH

+ Os

OsO4pyridine

Ch. 8 - 79

Both reagents give syn dihydroxylation

H H

H H

OH OH

or OsO4, pyridinethen NaHSO3

(cis-diol)

dil. KMnO4OH , H2O, cold

Ch. 8 - 80

Comparison of the two reagents●KMnO4: usually lower yield and

possibly side products due to over-oxidation

O

OH

OH

O+1. KMnO4,

2. H+

●OsO4: usually much higher yield but OsO4 is extremely toxic

(oxidative cleavage of C=C)

Ch. 8 - 81

17.Oxidative Cleavage of Alkenes

17A. Cleavage with Hot Basic Potassium Permanganate

KMnO4, OH , H2O

O

O

a2

or

O

OH2

H3O

b

a

b

a

b

ab a

b

ab

Ch. 8 - 82

Other examples

1. KMnO4, OH , H2O, heat

2. H3O O

O C O

+

(1)

O

O

OH

1. KMnO4, OH , H2O, heat

2. H3O(2)

Ch. 8 - 83

17B. Cleavage with Ozone

R'

R

H

R"

O

R'

R

O

H

R"1. O3+

2. Zn, AcOH or Me2S

Ch. 8 - 84

Examples

(1)1. O3

2. Zn, AcOH

O

O

+

(2)O

H

O

1. O3

2. Me2S

Ch. 8 - 85

Mechanism

C C

OO

O

CO

C

OO

C C

OO

O

initial ozonide

C

O

C

OO

+

O O

CO

C

ozonide +C O CO

+Zn(OAc)2

Ch. 8 - 86

18.Electrophilic Addition of Bromine & Chlorine to Alkynes

C CR H

X

C C

X

R

X

H

XCH2Cl2

(X = Cl, Br, I)

X2 (excess)

C CR H

X

C C

X

R

X

H

X

C C

H

X

X

H X2X2

(anti-addition)

Ch. 8 - 87

19.Addition of Hydrogen Halidesto Alkynes

C CR H

X

C C

H

R

X

H

H(X = Cl, Br, I)

X (excess)H

Regioselectivity●Follow Markovnikov’s rule

C C

Br

CH3

Br

H

H

Hgem-dibromide

C CH3C HHBr

C C

CH3

Br

H

H HBr

Ch. 8 - 88

Mechanism

C CCH3 HH Br

C C

H

H

CH3Br

C C

CH3

Br

H

H

C C

H

H

HCH3

BrBrC

H

H

H

C

Br

CH3

Br

H Br

Ch. 8 - 89

Anti-Markovnikov addition of hydrogen bromide to alkynes occurs when peroxides are present in the reaction mixture

H Br

peroxidesBr

H

(E) and (Z)

(74%)

Ch. 8 - 90

20.Oxidative Cleavage of Alkynes

C CR R' + R'CO2H1. O3

2. HOAcRCO2H

C CR R' + R'CO2H1. KMnO4, OH

2. H3O+

RCO2H

Example1. O3

2. AcOHC CPh CH3 PhCO2H + CH3CO2H

OR

Ch. 8 - 91

21.How to Plan a Synthesis:Some Approaches & Examples

In planning a synthesis we often have to consider four interrelated aspects:1. Construction of the carbon

skeleton2. Functional group

interconversions3. Control of regiochemistry4. Control of stereochemistry

Ch. 8 - 92

How to synthesize ?

OH

(target molecule) (precursor)

OH

●Retrosynthetic analysis

21A. Retrosynthetic Analysis

Ch. 8 - 93

●Synthesis

OH

H+

H2O

1. Hg(OAc)2, THF-H2O

2. NaBH4, OH

or

Markovnikov additionof H2O

Ch. 8 - 94

How to synthesize ?

(target molecule) (precursor)

OH

OH

●Retrosynthetic analysis

●Synthesis

OH

1. BH3-THF

2. H2O2, OH

anti-Markovnikov addition of H2O

Ch. 8 - 95

One approach to retrosynthetic analysis is to consider a retrosynthetic step as a “disconnection” of one of the bonds

In general, we call the fragments of a hypothetical retrosynthetic disconnection Synthons

21B. Disconnections, Synthons, and Synthetic Equivalents

Ch. 8 - 96

Example

HPhPh

CH3

Br BrHow?

●Retrosynthetic analysis

CH3PhPh

CH3

Br Br(i)

(gem-dibromide came from addition of HBr across a C≡C bond)

Ch. 8 - 97

●Retrosynthetic analysis

CH3Ph(ii)

disconnection

Ph + CH3

Ph Na+H3C I

synthons

synthetic equivalent

Ch. 8 - 98

●Synthesis

Ph Na

H3C I

Ph HNaNH2

liq. NH3

-30oC

(via an SN2 reaction)

Ph CH3HBr

(excess)PhCH3

Br Br

Ch. 8 - 99

21C. Stereochemical Considerations

CH3H3C

How?

H3C

BrBr

CH3

Ch. 8 - 100

Retrosynthetic analysis●The precursor of a vicinal

dibromide is usually an alkene●Bromination of alkenes are anti

addition

H3C

BrBr

CH3

(rotate 180o)

H3CCH3

Br

Br

H3CCH3CH3H3C

(anti addition of Br2)

(anti addition of H2)

Ch. 8 - 101

●Synthesis

H3C CH32. NH4Cl

1. Li, liq. NH3

H3CCH3

Br2/CCl4

H3CCH3

Br

BrH3C

Br

CH3

Br same

as

(anti addition of Br2)

(anti addition of H2)

Ch. 8 - 102

END OF CHAPTER 8