optical activity enantiomers are different compounds: same boiling point, melting point, density...
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Optical Activity
Enantiomers are different compounds: Same boiling point, melting point,
density Same refractive index
Rotate plane polarized light in opposite directions (polarimetry)
Different interaction with other chiral molecules EnzymesTaste buds, scent
Optical Activity
Polarimetry is a laboratory technique that measures the interaction between a compound and plane polarized light.
Since enantiomers interact with plane polarized light differently, polarimetry can be used to distinquish between enantiomers.
Optical Activity
“Regular” (unpolarized) light vibrates in all directions.
Plane-polarized light: light composed of waves that vibrate
in only a single plane obtained by passing unpolarized light
through a polarizing filter
Optical Activity
When plane polarized light passes through a solution containing a single chiral compound, the chiral compound causes the plane of vibration to rotate.
Polarimeter
Optical Activity
Chiral compounds are optically active: capable of rotating the plane of
polarized light
Enantiomers rotate the plane of polarized light by exactly the same amount but in opposite directions.
C
CH3
CH2CH3H
HO
C
C
CH3
CH2CH3H
HO
HOH
CH3
CH3CH2
(S)-2-butanol (R)-2-butanol
+13.5o rotation -13.5o rotation
Optical Activity
Compounds that rotate the plane of polarized light to the right (clockwise) are called dextrorotatory.
d(+) IUPAC convention
Compounds that rotate the plane of polarized light to the left (counterclockwise) are called levorotatory.
l(-) IUPAC convention
Optical Activity
The direction and magnitude of rotation must be determined experimentally. There is NO CORRELATION between (R)
and (S) configuration and the direction of rotation.
C
CH3
CH2CH3H
HO
C
C
CH3
CH2CH3H
HO
HOH
CH3
CH3CH2
(+)-2-butanol (-)-2-butanol
+13.5o rotation -13.5o rotation
(S)-(+)-2-butanol (R)-(-)-2-butanol
Optical Activity
(S)-(-)-thyroxinebiologically activeO CH2
CCO
2H
HH2NI I
II
HO
O CH2HO
I
I I
IC
CO2H
NH2
H
(R)-(+)-thyroxineinactive
O CH2
CCO
2H
HH2NI I
II
HO
O CH2HO
I
I I
IC
CO2H
NH2
H
Unlike (R)-(-)-2-butanol, (R)-thyroxine rotates light to the right.
Optical Activity
The angular rotation observed in a polarimeter depends on: the optical activity of the compound the concentration of the sample the path length of the sample cell
A compound’s specific rotation [] can be used as a characteristic physical property of a compound: the rotation observed using a 10-cm
sample cell and a concentration of 1 g/mL.
Optical Activity
lc
observed
)(][
where a = specific rotation
c = concentration in g/mL
l = path length in dm
a (observed) = rotation observed for a specific sample
Optical Activity
Example: A solution of 2.0 g of (+)-glyceraldehyde in 10.0 mL of water was placed in a 100. mm polarimeter tube. Using the sodium D line, a rotation of 1.74o was observed at 25oC. Calculate the specific rotation of (+)-glyceraldehyde.
lc
observed
)(][
Optical Activity
dmm
dm
mm
mmml 00.1
1
10
1000
1.100
mLgml
gc 20.0
0.10
0.2
Given: (obs) = 1.74o
o7.800.120.0
74.1][
Find: []
Optical Activity
A mixture containing equal amounts of (+)-2-butanol and (-)-2-butanol gives an observed rotation of zero degrees Just like an achiral molecule
C
CH3
CH2CH3H
HO
C
C
CH3
CH2CH3H
HO
HOH
CH3
CH3CH2
+13.5o rotation -13.5o rotation
(S)-(+)-2-butanol (R)-(-)-2-butanol
Optical Activity
A solution containing equal amounts of two enantiomers is called a racemic mixture. Racemate (+) pair (dl) pair
Racemic mixtures are optically inactive.
Racemic mixtures are designated using the prefix (+):
(+)-2-butanol
Optical Activity
Racemic mixtures are often formed during chemical reactions when the reactants and catalysts used are achiral.
Optical Activity
Some mixtures are neither optically pure (all one enantiomer) nor racemic (equal mixture of both enantiomers).
Optical purity: Ratio of the rotation of a mixture to
the rotation of a pure enantiomer
o.p. = observed rotation x 100%
rotation of pure enantiomer
Optical Activity
Example: (-)-2-butanol has a specific rotation of - 13.5o while the specific rotation of (+)-2-butanol is +13.5o. A mixture containing (+) and (-)-2-butanol has an observed rotation of – 8.55o. Does the mixture contain more (+) or more (-)-2-butanol? Calculate the optical purity of the mixture.
Optical Activity
Another method to express (or determine) the relative amounts of enantiomers present in a mixture is enantiomeric excess. Numerically identical to optical purity
e.e. = o.p. = excess of one over the other x 100%
entire mixture
%100.. xld
ldee
Optical Activity
Example: Calculate the e.e of a mixture containing 25% (+)-2-butanol and 75% (-)-2-butanol.
Optical Activity
Example: Calculate the relative proportions of (+)-2-butanol and (-)-2-butanol required to give an observed rotation of +0.45o if the specific rotation of (+)-2-butanol is 13.5o.
Optical Activity
Any (or all) of a set of diastereomers may be optically active (if it has a non-superimposable mirror image)
Pairs of optically active diastereomers rotate light by different amounts.
C
O
HOHHOHOH
CH2OHHH
HHO
COHHHHO
OHHCH2OH
O
H
H OH
C
O
HOHHOHOH
CH2OHHH
HHO
COHHHHO
OHHCH2OH
O
H
HHO(+)-glucose
+ 52.5o
(+)-galactose+ 83.9o
Separation of Stereoisomers & Structural Isomers
Structural isomers and diastereomers have different physical properties: BP, MP, density, refractive index,
solubility
Can be separated through conventional means (distillation, recrystallization, chromatography)
H BrCO2H
CO2HBr H
CO2H
Co2H
HH
BrBr
H BrCO2H
CO2HBr H
CO2H
CO2H
HH
BrBr
MP = 158oC MP = 256oC
Resolution of Enantiomers
Since enantiomers have identical physical properties, they cannot be separated by conventional methods. Distillation and recrystallization fail.
The process of separating enantiomers is called resolution.
Two methods: chemical resolution chromatographic resolution
Resolution of Enantiomers
Chemical resolution of enantiomers: temporarily convert both enantiomers
into diastereomersreact with an enantiomerically pure (natural) product
separate the diastereomers based on differences in physical properties
convert each diastereomer back into the original enantiomer
Resolution of Enantiomers
Chromatographic resolution of enantiomers: Prepare column containing stationary
phase coated with a chiral compound
Enantiomers form diastereomeric complexes with the chiral stationary phase
Separate the diastereomeric complexes based on differences in affinity for stationary phasestrongly complexed: elutes slowlyweakly complexed: elutes more quickly
Chiral Compounds w/o Asymmetric Atoms
Although most chiral compounds have at least one asymmetric atom, there are some chiral compounds that have zero asymmetric atoms: conformation enantiomers allenes
Chiral Compounds w/o Asymmetric Atoms Conformational enantiomers:
compounds that are so bulky or so highly strained that they cannot easily confert from one chiral conformation to the mirror-image conformation“locked” into one conformation