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Second Year Organic Chemistry CourseCHM3A2
Frontier Molecular Orbitals and Pericyclic Reactions
Part 2(i):
Electrocyclic Reactions
An electrocyclic reaction involves the formation of a -bond between the termini of a linear conjugated -system by two of the -electrons - or the reverse reaction.
MeMe
HOMO
MeMe
HOMOn n
DISROTATORY CONROTATORY
– Learning Objectives Part 2(i) –
Electrocyclic Reactions
CHM3A2– Introduction to FMOs –
After completing PART 2(i) of this course you should have an understanding of, and be able to demonstrate, the
following terms, ideas and methods.
(i) An electrocyclic reaction involves the formation of a -bond between the termini of a linear
conjugated -system by two of the -electrons - or the reverse reaction.
(ii) Electrocyclic reactions are stereospecific. The stereospecificity being afforded by the disrotatory
or conrotatory nature of the bond making/breaking process
(iii) 4-electron systems are conrotatory when thermally promoted, (and disrotatory when
photochemically promoted - CHM3A2).
(iv) 6-electron systems are disrotatory when thermally promoted (and conrotatory when
photochemically promoted - CHM3A2).
(v) The disrotatory or conrotatory process involved in the bond making/breaking process is controlled
by the HOMO (thermal reaction) or SOMO (photochemical reaction - CHM3A2) of the linear
conjugated -system which either is the starting material or product.
Meso
MeMe MeMe
6-Electron Systems
Me
Me
MeMe
MeMe
MeMe
MeMe
SS
RR
RS
Enantiomers
SS
RR
RS
MeMe MeMe
MeMe MeMe MeMe
MeMe
MeMe
Enantiomers
4-Electron Systems
Meso
HOMOs of Polyenes
A new -bond is forming at the termini of each of the polyene systems.
Thus, it is clear that the -system of the polyene systems must be interacting in
some fashion.
Analysis of the polyenes has shown that by considering the HOMOs, and
rotating the termini of them to overlap them in an in-phase fashion produces the
correct stereochemical outcome.
The termini of the orbitals can be rotated in two manners referred to as:
Conrotatory,
Disrotatory.
Disrotatory Motion: Dark/Dark
MeMe
n
MeMe
n
MeMe
n
In-phase
Meso
Disrotatory Motion: Light/Light
MeMe
n
MeMe
n
MeMe
n
In-phase
Meso
Conrotatory Motion: Dark/Dark
MeMe
n
MeMe
n
MeMe
n
In-phase
RSEnantiomer
Conrotatory Motion: Light/Light
MeMe
n
MeMe
n
MeMe
n
In-phase
SREnantiomer
4n+2 Electron Electrocyclic Reactions
Disrotatory
3 – HOMO1, 3, 5-Hexatriene
6 p AOS
6 MOs
6 Electrons
3 = HOMO
two nodes (7/3)
RR and SS (enantiomers)
MeMe Me
Me
3 – HOMO
Meso
DISROTATORY DISROTATORY
Dark/DarkOr
Light/Light
Butadiene
4n Electron Electrocyclic Reactions
4n Electron Electrocyclic Reactions
Conrotatory
2 – HOMOButadiene
4 p AOS
4 MOs
4 Electrons
2 = HOMO
one node (5/2)
Dark/DarkOr
Light/Light
RR and SS (enantiomers) see next slide Meso
2 – HOMO
CONROTATORY CONROTATORY
Enantiomer Formation
Two alternative and equivalent modes of conrotatory in-phase
overlap
2 – HOMO
CONROTATORY CONROTATORY
RR SS
A Pair of Enantiomers
Coping with Ring Opening Reactions
1. Draw out the -HOMO of the product without the substituents
2 HOMO
2. Draw out the MO of the Starting material
2 HOMOBonding: Must be in phase!
Same Phase
3. Open the C-C bond two afford the HOMO of the product
2 HOMOCONROTATORY
4. Decide how the substituents moveProduct
stereochemistry
2 HOMOCONROTATORY
_______________________________________________________Number of -Electrons Thermal Photochemical
(CHM3A2)
4n CONrotatory DISrotatory4n + 2 DISrotatory CONrotatory_______________________________________________________
Rules for Electrocyclic Reactions
Photochemical reactions will be dealt with in the third year course (CHM3A2), where the first electronically excited stated state becomes the HOMO.
– Summary Sheet Part 2(i) –
Electrocyclic Reactions
CHM3A2– Introduction to FMOs –
An electrocyclic reaction involves the formation of a -bond between the terminals of a linear conjugated -system
by two of the -electrons – or the reverse process.
Electrocyclic reactions are either 'allowed' or 'forbidden' – and they are stereospecific, occurring by either a so-
called conrotatory or disrotatory motion.
Electrocyclic reactions can be brought about by heat (CHM2C3B), by ultraviolet irradiation (CHM3A2), and
sometimes by the use of metal catalysts (CHM3A2). They are nearly always stereospecific. In many cases,
detection of their stereospecificity depends on distinguishing chemically similar stereoisomers - a problem which
has been overcome mainly by the development of spectroscopic methods of structure determination, especially
NMR spectroscopy. Thus, the recognition that stereospecific electrocyclic reactions form a coherent group
extends only over the last quarter of a century. Nowadays, the group includes some important synthetic reactions
as well as some of the most clear cut examples of the successful predictive power of orbital symmetry theory.
In the case of 6 systems, the thermal ring closure of 1,3,5-hexatrienes to conjugated cyclohexadienes is
stereospecific - and disrotatory - as the theory predicts. Ring closure of 1,3, 5-hexatrienes is a relative facile
process relative to butadiene ring closure which generates a highly strained butadiene derivatives.
In the case of 4 systems, the thermal ring opening of cyclobutenes to butadienes is stereospecific - and
conrotatory - as the theory predicts. In most cases, the ring opening goes to completion and there are very few
examples of the reverse process, the thermal cyclisation of butadienes. Fused cyclobutenes, however, are
thermally rather stable, especially those in which the second ring is five- or six-membered.
Exercise 1: 4n+2 Electrocylic Systems
The triene 1 undergoes a thermal electrocyclic cyclisation. Using FMOs identify all the products.
1
Answer 1: 4n+2 Electrocylic Systems
The triene 1 undergoes a thermal electrocyclic cyclisation. Using FMOs identify all the products.
1
Superimposable Mirror Images
Exactly the same compound
MESO Compound
RS
DarkDark
R S
LightLight
DISROTATORY
3 – HOMO
Exercise 2: 4n+2 Electrocylic Systems
1 2
The two diastereoismeric trienes 1 and 2 undergo thermal electrocyclic cyclisation reactions each affording a pair of disubstituted conjugated cyclic dienes. Identify all four products by constructing the transition state geometries, and state the stereochemical relationships that exist between the pairs of stereoisomers formed from each reaction and the stereochemical relationship of the products between the pair of reactions
Answer 2: 4n+2 Electrocylic Systems
The two diastereoismeric trienes 1 and 2 undergo thermal electrocyclic cyclisation reactions each affording a pair of disubstituted conjugated cyclic dienes. Identify all four products by constructing the transition state geometries, and state the stereochemical relationships that exist between the pairs of stereoisimers formed from each reaction and the stereochemical relationship of the products between the pair of reactions
1 2
3 – HOMO
Enantiomers EnantiomersDiasteroisomersRS
DarkDark
R R
DarkDark
R S
LightLight
S S
LightLight
DISROTATORY DISROTATORY
Exercise 3: 4n Electrocylic Systems
The cyclobutadiene derivative undergoes an stereospecific electrocyclic ring opening reaction to afford a single product. Utilise FMOs to identify the product.
1
Answer 3: 4n Electrocylic Systems
The cyclobutadiene derivative undergoes an stereospecific electrocyclic ring opening reaction to afford a single product. Utilise FMOs to identify the product.
1
CONROTATORY 2 HOMO
Exercise 4: A Cascade Electrocylic System
MeMe
HH
MeMeMe Me
HH
Use FMOs to predict the stereochemical outcomes in the reaction scheme below.
Answer 4: A Cascade Electrocylic System
Use FMOs to predict the stereochemical outcomes in the reaction scheme below.
MeMe
HH
MeMeMe Me
HH
MeMe
(3 nodes 9/4)of 1, 3, 5, 7-octatetraene
4n - CONROTATORY
Me Me
HH
(2 nodes)
of 1, 3, 5-hexatriene
(4n + 2) - DISROTATORY
MeMe
HH
MeMeMe Me
HH
Me Me
HHHH
MeMe
Dark/Dark Dark/Dark
Light/Light Light/Light
Exercise 5: Tandem Electrocyclic Reaction
Use FMOs to predict the stereochemical outcomes in the reaction scheme right. In principle, there are two possible products. Which will be formed in highest yield. Justify your answer.
H
H
H
H
Answer 5: Tandem Electrocyclic Reaction
Use FMOs to predict the stereochemical outcomes in the reaction scheme right. In principle, there are two possible products. Which will be formed in highest yield. Justify your answer.
H
H
H
H
The arrow pushing mechanism reveals that the reaction involves the ring closure of two 1,3,5-hexatriene systems. Thus, need to consider 3 HOMO of 1, 3, 5-hexatriene.
HH
HH
Thermodynamic Product. Least
sterically hinderedDisrotatoryof both
triene systems
LightLight
H
H
H
H
H
H
H
H
LightLight
LightLight
DarkDark
Exercise 6: Complex Electrocyclic Reaction
Cyclooctatetraene undergoes an
electrocyclic ring closure forming only
the cis-isomer as depicted right.
Rationalise this result using FMOs.
HH H H
0% 100%
Answer 6: Complex Electrocyclic Reaction
Cyclooctatetraene undergoes an
electrocyclic ring closure forming only
the cis-isomer as depicted right.
Rationalise this result using FMOs.
HH H H
0% 100%4 Electron Process
6 Electron Process
Thus, the reaction must proceed by a 6electron process, despite the 4 electron process being
possible by FMO theory. Reasons for formation of cis-isomer are possibly two-fold: (i) cis-isomer is
the thermodynamically more stable product, and/or (ii) the aromatic 6 electron aromatic transition
state is lower in energy than the 4 electron anti-aromatic transition state.
H H
CONROTATORY
HH
2
HOMO
Butadiene
HH
H H
DISROTATORY
3
HOMO
1,3,5-Hexatriene
Exercise: 4n Electrons Electrocyclic Reactions
Using FMOs rationalise why the two
diastereoisomers have such different reactivities.
H H
H H
Answer: 4n Electrons Electrocyclic Reactions
Using FMOs rationalise why the two
diastereoisomers have such different reactivities.
H H
H H
H HH
H
H H HH
CON
H H
H H H
HH
H
GEOMETRICALLY IMPOSSIBLE: Hydrogen placed
inside a six-membered ring
CON
