Organic Chemistry CHM113M Course Lecture 4 PDF

Summary

This is a lecture on organic chemistry, specifically covering chirality without chiral centers, allenes, spiro compounds, biphenyls, and helicenes. The lecture is part of the CHM113M course at IIT Kanpur, semester I, 2024-2025.

Full Transcript

Organic Chemistry

CHM113M Course (Lect. 4)
Sem I (2024-25)

Instructor: Dr. V. S. Mothika
Department of Chemistry
IIT Kanpur
1
Chirality without a chiral center
Molecules can be chiral without having chiral centers for example when a compound has a "screw-
like" structure due to restricted rotation caused by connecting bonds or spatial steric crowding
They are chiral about an axis and contain two non-superimposable mirror images. This termed as
Axial chirality

Allenes Spiro compounds

Biphenyl
compounds Helicenes

2
Axially chiral systems does not need stereocenter

Allene
Helical

(-)-Panacene
(biologically active)

Vancomycin
(Antibiotic)

Biphenyl

Helical Nanographenes
(Electronics)

Spiro
Zebofloxacin
(Antibiotic) 3
Atropisomerism and biphenyls
Atropisomerism: It occurs when a molecule experiences a high enough steric strain that creates a
barrier between substituents, which prevents pivotal bond rotation and forms different isomers of
the compound.
Biphenyls dynamically convert between two isomers via a high energy Achiral transition state (TS)
Atropisomers are physically separable by chiral HPLC if they have sufficiently high racemization
energy and half-life >16.7 min at room temperature.

Repulsive
interactions

Twist angle,
θ = 0/180/360°
ΔG‡ = 3 kcal/mol
High steric strain
Good π-conjugation

Twist angle At Twist angle
θ = 45/135/225/315° θ = 90°
Low steric strain No steric strain
Good π-conjugation Poor π-conjugation
4
Axially chiral systems does not need stereocenter
The TS is achiral due to presence of symmetry. The central bond about which rotation occurs is
also called pivotal bond. Maximum steric strain is observed in TS1 and is of highest energy
Unlike biphenyl, here the twist angle where the minima is observed is slightly greater than 45°

High steric
repulsion TS1

TS1 TS2
ΔG‡ = ΔG‡ = 8-10
19-20 kcal/mol
kcal/mol

(S)- (R)-
Isomer Isomer

Rotate right
Turn molecule
hand ring by
by 180°
180° around
C-C bond

5
Nomenclature system
Step 1: Identify the viewing direction.
Step2: rank the two substituents on each phenyl ring in the order of priority.
Step 3: Look from the side of flat structure along the pivotal bond axis and draw the projection in
line form with front ring with thick line and back ring with a circle.
Place the substituents on either side as you would see.
Identify the movement from the highest priority substitution on the front carbon to the highest
priority substitution on the back carbon.
If clockwise, configuration is denoted as “R-enantiomer” and if anticlockwise, configuration is “S-
enantiomer”.

1 1
Me Me
4 3
H Me Me H4
3
H 2 H
Me > H 2

Anticlockwise clockwise
(S)-isomer (R)-isomer
6
Nomenclature system
Binaphthyls also show atropisomerism. For R/S-configuration similar rules can be applied

2
Ph
4
Ph PPh2
3
PPh2
1

Clockwise
BINAP (R)-isomer

1
PPh2
4
Ph PPh2
3
Ph
2

Anticlockwise
(S)-isomer
3D models
7
BINAP = 2,2′-Bis(diphenylphosphino)-1,1′- binaphthyl
Allenes structure and bonding
Allenes are compounds which have two cumulative double bonds (two double bonds adjacent to
each other).
The terminal carbon atoms are sp2 hybridized while the central carbon atom is sp hybridized.
The bonding dictates that the two p-bonds be in perpendicular planes.

Blue are σ-bonds
Green are π-bonds 8
Chirality in allenes
If the two substituents on the terminal carbon atoms are distinct, then the allene is chiral.

Plane of
symmetry
Achiral
No plane of
symmetry
Chiral
9
R, S-Configuration of allenes
The “R” and “S” nomenclature applies to allenes as well.
A similar method used for naming biaryls can be followed to identify the stereochemical
configuration of allenes

1 1
Me Me

3 4
Me H H Me 3
4
H
H 2
2

clockwise Anticlockwise
(R)-isomer (S)-isomer

10
R, S-Configuration of spiro systems
The “R” and “S” nomenclature applies to spiro compounds as well.
Here spiro carbon is tetrahedral, depending on viewing direction 1st and 2nd priority is given
to both sides of spiro center and then the 3rd and 4th priority order is assigned.

1 4 3 2

2 (S)
3 1 4

4 3 2
1
(S)
2 1
3 4

Clockwise AntiClockwise
(R)-isomer (S)-isomer

(S)
11
R, S-Configuration of helicenes
The “R” and “S” nomenclature applies to helicenes as well.
Step 1 - identify the axis of the helix.
Step 2 - look along the axis. If the molecule rotates clockwise as you move from the front to the rear (away
from viewer), the descriptor is P or plus. If the molecule rotates anticlockwise direction, it is M or minus.

12
Nucleophilic Substitution
Reactions

13
Alkyl halides
Tetrahedral ‘C’ ; sp3 hybridized
C-X bond is polarized and result partial positive charge on C and negative charge on ‘X’ (X =
halogen here). This results in intermolecular dipole-dipole attractions and high boiling
point to alkyl halides if compared to alkanes.

*ESP map

14
*ESP is electrostatic potential surface; red surface indicates high e− density region
Polarity of Alkyl halide bonds
Increase in C-X bond length
1.39 Å 2.14 Å

110 57
Kcal/mol Decrease in C-X bond strength Kcal/mol

15
How alkyl halides react
Halogen (X) is more electronegative than carbon and the bonded electrons are not shared equally
but polarized towards halogen
Nu− is nucleophile, X− is leaving group and ‘C’ is electrophilic center

Path 1:
(SN2)

Path 2:
(SN1)

16
Bimolecular Nu− substitution reaction: SN2
SN2 reaction, where “S” stands for substitution, “N” for nucleophilic, and “2” for bimolecular.
Bimolecular means that two molecules are involved in the rate-determining step.
SN2 reaction is a concerted reaction—it takes place in a single step. No intermediates are
formed. The nucleophile (OH− here) attacks the carbon bearing the leaving group (Br−
here) and displaces the leaving group. Rate ∝ [alkyl halide][nucleophile]
Energy (kJ/mol)

17
Stereoelectronics of SN2
The configuration of that product is inverted relative to
the configuration of the alkyl halide. Only one product
formed since SN2 is concerted reaction

LUMO of CH3Br

Configuration
is inverted

18
Why rear attack preference
Back-side attack involves a bonding interaction between the Nu− and the larger lobe of σ*
when the nucleophile approaches the front side of the carbon: Both a bonding and an antibonding
interaction occur, and the two cancel each other.

19
Factors affecting SN2: Sterics at electrophilic ‘C’

Accessibility of electrophilic ‘C’ center by Nu and reaction rate
20
Effects of sterics at electrophilic ‘C’ center
Reaction coordinate diagrams for (a) the reaction of methyl bromide with hydroxide ion; (b)
an reaction of a sterically hindered alkyl bromide with hydroxide ion.
Transition state energy increases with increase in the steric bulk at the electron carbon
center
Single step (via formation of transition state)
Bonds broken and formed simultaneously

21
The Nucleophile
Basicity is a measure of affinity towards proton (equilibrium process)—thermodynamic
property
Nucleophilicity is a measure of reactivity towards an electrophilic carbon (kinetic property)
(irreversible process and measured by rate of reaction)
In protic solvents, larger ions with diffused electron density are less solvated and also their
HOMO can interact better with LUMO of ‘C’ at larger distances such as TS.

Nucleophilicity increases from top to down in porotic solvents

Nucleophilicity decreases with steric bulk

22
The Nucleophile
Basicity broadly parallels nucleophilicity
Less stable anions are stronger Nu− than more stable anions

R-O− > RCOO−
(Alkoxide) (carboxylate)
Nucleophilicity decreases from left to right due to increases in electronegativity of Nu− center

Conjugate base is stronger Nu− due to increased electron density on Nucleophilic center

23
Leaving group ability and basicity
The weaker the basicity of a group, the better is its leaving ability.
Weak bases don’t share their electrons well, a weak base is not bonded as
strongly to the carbon as a strong base

24
Good leaving group stabilizes the negative charge
A leaving group that can stabilize negative charge better will be a better leaving
group.
Charge delocalization is an important indicator of relative stability

Good leaving groups

1/2

1/2

p-toluenesulfonate anion stable due
(OTs) to resonance
25
Converting a bad LG to good LG

26
Polar protic solvent
Protic solvent (e.g., CH3OH, H2O) stabilizes the initial state thus, Nu− itself over TS thus
the reaction slows down. On the other hand, protic solvent stabilizes more polar TS if
neutral nucleophile is used thus speeding up the reaction.

(a)

(b)
27
Polar protic solvent hinders SN2 reactivity
Protic solvents: Protic solvents (e.g., CH3OH, H2O) are hydrogen bond donors. They
solvate and shields the Nucleophile through ion-dipole interactions.
Weak bases interact weakly with protic solvents, whereas strong bases interact more
strongly because they are better at sharing their electrons.
Fluoride ion would be a better nucleophile in a nonpolar solvent than in a polar solvent

28
Polar aprotic solvent good for SN2 reaction
Aprotic polar solvents (DMSO, DMF) does not have a hydrogen attached to an
oxygen or to a nitrogen.
The molecules of an aprotic polar solvent have a partial negative charge on
their surface that can solvate cations leaving Nu− behind.
Fluoride ion, therefore, is a better nucleophile in DMSO than it is in water.

29
Influence of solvent on SN2 reaction
Aprotic solvents raise the energy of Nu− which results in lower Ea and a faster
SN2 reaction

30
Unimolecular Nu− substitution reaction: SN1
The SN1 reaction is a unimolecular nucleophilic substitution.
It has a carbocation intermediate.
Rate = kr[alkyl halide] i.e. doubling alkyl halide concentration doubles rate
If precursor is enantiopure, racemic mixture of products obtained

Racemic mixture forms.

(S) (S) (R)

31
Energetics of SN1 reaction
Two transition states (TS) formed: TS1 with Leaving group and TS2 with incoming Nu
The lower energy of TS2 over TS1 favors the reaction forward.

32
Stable carbocation formation favors SN1
Alkylhalides that forms stable carbocation reacts faster
Stability of carbocation increases with increasing methyl substitution

33
Stability of Carbocations
Electron sharing between C-H sigma bond and vacant p-orbital of positively charged ‘C’
stabilizes carbocation

No Hyperconjugation
in CH3+

Hyperconjugation and
Electron pumping
into vacant p-orbital of
3° carbocation

34
Stability of Carbocations
Electronic effects such as inductive effect, conjugation stabilizes the carbocation

35
Stability of allyl and benzyl carbocations
sp2 carbon attached carbocations stabilize by resonance
Allyl carbocation: Resonance hybrid

HOMO of allyl cation
Benzyl carbocation:

36
Aromaticity and Dancing resonance
Aromatization stabilizes carbocation

Conjugation between bent
orbital of cyclopropyl ring
and vacant p-orbital of
carbocation
This is called dancing
Resonance
Stability increases with
addition of each cyclopropyl
group

37
Hydride shift in Carbocations
Hydride shifts are very fast (faster than SN1) which is partially due to hyperconjugation in the
carbocation weakening the C-H bond)

More stable

38
Hydride shift in Carbocations
1,2-Hydride shift occurs in SN1 reactions to form more stable carbocation.
Below is the hydride shift in SN1 reaction of alkyl halide with H2O

39
Neighbouring group participation
Groups remote from a reaction centre can participate in substitution reactions – Neighboring
Group Participation (NGP) (or anchimeric assistance):
lone pairs of electrons, typically on N, O, S or Hal atoms interact with electron
deficient/cationic centres
NGP is characterized by reaction rate acceleration

SN2 reaction
(Inversion)
Relative rate 1

Relative rate
600 Double
2-chloroethyl
SN2 reaction
phenyl sulfide
(Retention)

40
Neighbouring group participation
SN2 results in inversion in configuration
Retention in stereochemical configuration in NGP assisted SN2 is due to double inversion
So NGP can manifest stereochemical outcome of the reaction

α-Amino acid

Overall
Retention of
stereochemistry
α-hydroxy acid

41
Nucleophilic substitution internal (SNi) reaction
SNi reactions results in retention of configuration
Chlorination of alcohol by SNi is mediated through an tightly held intimate ion pair formation
Unlike SN1, no actual carbocation generated rather it is an ion pair (otherwise we get
racemized product as like SN1). Rate of SNi = k[ROH][SOCl2]
if the alcohol is chiral then this results in retention of configuration

(Retention) 42
END

43