Organic Chemistry Lecture 9th Edition - Chapter 5 - PDF

Summary

These lecture notes cover the important concept of stereochemistry within the broader field of organic chemistry. The document explores topics like chiral and achiral compounds, stereoisomers, and chiral carbon atoms, providing fundamental knowledge for students of chemistry.

Full Transcript

Organic Chemistry,
9th Edition
L. G. Wade, Jr.

Chapter 5
Lecture
Stereochemistry

Chad Snyder, PhD
Grace College
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 Chirality

“Handedness”: Right-hand glove does not fit the left hand.
An object is chiral if its mirror image is different from the
original object.

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 Achiral
Mirror images that can be superposed are achiral
(not chiral).

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 Stereoisomers
Enantiomers are compounds that are nonsuperimposable
mirror images. Any molecule that is chiral must have an
enantiomer.

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 Chiral Carbon Atom
Also called asymmetric carbon atom
A carbon atom that is bonded to four different groups is
chiral.
Its mirror image will be a different compound (enantiomer).

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 Stereocenters

An asymmetric carbon atom is the most common
example of a chirality center.
Chirality centers belong to an even broader group
called stereocenters. A stereocenter (or
stereogenic atom) is any atom at which the
interchange of two groups gives a stereoisomer.
Asymmetric carbons and the double-bonded
carbon atoms in cis-trans isomers are the most
common types of stereocenters.

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 Examples of Chirality Centers

Asymmetric carbon atoms are examples of chirality
centers, which are examples of stereocenters.
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 Achiral Compounds

Take this mirror image and try to
superimpose it on the one to the left
matching all the atoms. Everything
will match.

When the images can be superposed, the compound is achiral.
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 Planes of Symmetry

A molecule that has a plane of symmetry is achiral.
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 Cis Cyclic Compounds

Cis-1,2-dichlorocyclopentane is achiral because the
molecule has an internal plane of symmetry. Both structures
above can be superimposed.
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 Trans Cyclic Compounds

Trans-1,2-dichlorocyclopentane does not have a plane of
symmetry, so the images are nonsuperimposable and the
molecule will have two enantiomers.
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 (R) and (S) Configuration

Both enantiomers of alanine receive the same name in the IUPAC
system: 2-aminopropanoic acid.
Only one enantiomer is biologically active. In alanine only the left
enantiomer can be metabolized by the enzyme.
We need a way to distinguish between them.
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 Cahn–Ingold–Prelog
Convention
Enantiomers have different spatial arrangements of
the four groups attached to the asymmetric carbon.
The two possible spatial arrangements will be
called configurations.
Each asymmetric carbon atom is assigned a letter,
(R) or (S), based on its three-dimensional
configuration.
Cahn–Ingold–Prelog convention is the most
widely accepted system for naming the
configurations of chirality centers.
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 (R) and (S) Configuration:
Step 1 Assign Priority
Assign a relative “priority” to each group bonded to
the asymmetric carbon. Group 1 would have the
highest priority, group 2 second highest, etc.
Atoms with higher atomic numbers receive higher
priorities.

I > Br > Cl > S > F > O > N > 13C > 12C > Li > 2H > 1H

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 Assign Priorities

Atomic number: F > N > C > H
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 (R) and (S) Configuration:
Breaking Ties

In case of ties, use the next atoms along the chain of each
group as tiebreakers.

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 (R) and (S) Configuration:
Multiple Bonds

Treat double and triple
bonds as if each were a
bond to a separate atom.

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 (R) and (S) Configuration:
Step 2
Working in 3-D, rotate
the molecule so that the
lowest priority group is in
back.
Draw an arrow from the
highest to lowest priority
group.
Clockwise = (R)
Counterclockwise = (S)

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 Assign Priorities

Counterclockwise
(S)

Draw an arrow from Group 1 to Group 2 to Group 3 and
back to Group 1. Ignore Group 4.

Clockwise = (R) and Counterclockwise = (S)
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 Example

Clockwise
(R)

When rotating to put the lowest priority group in the back,
keep one group in place and rotate the other three.

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 Example (Continued)

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 Solved Problem 1
Draw the enantiomers of 1,3-dibromobutane and label them as (R) and (S). (Making a model
is particularly helpful for this type of problem.)

Solution
The third carbon atom in 1,3-dibromobutane is asymmetric. The bromine atom receives first
priority, the (–CH2CH2Br) group second priority, the methyl group third, and the hydrogen
fourth. The following mirror images are drawn with the hydrogen atom back, ready to assign
(R) or (S) as shown.

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 Configuration in Cyclic
Compounds

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 Properties of Enantiomers
Same boiling point, melting point, and density
Same refractive index
Rotate the plane of polarized light in the same
magnitude, but in opposite directions.
Different interaction with other chiral molecules
– Active site of enzymes is selective for a specific
enantiomer.
– Taste buds and scent receptors are also chiral.
Enantiomers may have different smells.

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 Polarized Light
Plane-polarized light is composed of waves that
vibrate in only one plane.

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 Optical Activity

Enantiomers rotate the plane of polarized light in opposite
directions, but in the same number of degrees.

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 Polarimeter

Clockwise Counterclockwise
Dextrorotatory (+) Levorotatory (–)

Not related to (R) and (S)
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 Specific Rotation
Observed rotation depends on the length of the cell
and concentration, as well as the strength of optical
activity, temperature, and wavelength of light.

where  (observed) is the rotation observed in the
polarimeter, c is concentration in g/mL, and l is length
of sample cell in decimeters.

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 Solved Problem 2
When one of the enantiomers of 2-butanol is placed in a polarimeter, the
observed rotation
is 4.05° counterclockwise. The solution was made by diluting 6 g of 2-
butanol to a total of 40 mL, and the solution was placed into a 200-mm
polarimeter tube for the measurement. Determine the specific rotation for
this enantiomer of 2-butanol.
Solution
Since it is levorotatory, this must be (–)-2-butanol The concentration is 6 g
per 40 mL = 0.15 g/mL, and the path length is 200 mm = 2 dm. The
specific rotation is

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 Biological Discrimination

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 Racemic Mixtures

Equal quantities of d- and l-enantiomers
Notation: (d,l) or ()
No optical activity
The mixture may have different boiling point (b. p.) and
melting point (m. p.) from the enantiomers!

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 Racemic Products
If optically inactive reagents combine to form a chiral
molecule, a racemic mixture is formed.

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 Optical Purity
Optical purity (o. p.) is sometimes called
enantiomeric excess (e. e.).
One enantiomer is present in greater amounts.

observed rotation
o. p. = × 100
rotation of pure enantiomer

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 Calculate % Composition
The specific rotation of (S)-2-iodobutane is +15.90°.
Determine the % composition of a mixture of (R)-
and (S)-2-iodobutane if the specific rotation of the
mixture is –3.18°.

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 Calculate % Composition
The specific rotation of (S)-2-iodobutane is +15.90.
Determine the % composition of a mixture of (R)-
and (S)-2-iodobutane if the specific rotation of the
mixture is -3.18.
Sign is from the enantiomer in excess: levorotatory.

3.18
o.p. = X 100 = 20%
15.90

l = 60% d = 40%
% Highest Enant. = (((100-ee)/2) + ee)
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 Chirality of Conformers
If equilibrium exists between two chiral
conformers, the molecule is not chiral.
Judge chirality by looking at the most
symmetrical conformer.
Cyclohexane can be considered to be
planar, on average.

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 Chirality of Conformational
Isomers

The two chair conformations of cis-1,2-dibromocyclohexane
are nonsuperimposable, but the interconversion is fast and the
molecules are in equilibrium. Any sample would be racemic
and, as such, optically inactive.
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 Nonmobile Conformers

The planar conformation of the biphenyl derivative is too
sterically crowded. The compound has no rotation around
the central C—C bond and, thus, it is conformationally
locked.
The staggered conformations are chiral; they are
nonsuperimposable mirror images.
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 Allenes

Some allenes are chiral even though they do not
have a chiral carbon.
Central carbon is sp hybridized.
To be chiral, the groups at the end carbons must
have different groups.

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 Penta-2,3-diene Is Chiral

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 Fischer Projections
Flat representation of a 3-D molecule
A chiral carbon is at the intersection of horizontal and vertical lines.
Horizontal lines are forward, out of plane.
Vertical lines are behind the plane.

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 Fischer Projections (Continued)

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 Fischer Rules
Carbon chain is on the vertical line.
Highest oxidized carbon is at the top.
Rotation of 180° in plane doesn’t change the
molecule.
Rotation of 90° is not allowed.

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 180° Rotation

A rotation of 180° is allowed because it will not change
the configuration.

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 90° Rotation

A 90° rotation will change the orientation of the horizontal
and vertical groups.
Do not rotate a Fischer projection 90°.
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 Glyceraldehyde
The arrow from group 1 to group 2 to group 3 appears
counterclockwise in the Fischer projection. If the
molecule is turned over so the hydrogen is in back, the
arrow is clockwise, so this is the (R) enantiomer of
glyceraldehyde.

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 HINT
When naming (R) and (S) from
Fischer projections with the
hydrogen on a horizontal bond
(toward you instead of away
from you), just apply the normal
rules backward.

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 Fischer Mirror Images
Fisher projections are easy to draw and make it easier to
find enantiomers and internal mirror planes when the
molecule has two or more chiral centers.

CH3
H Cl
Cl H
CH3

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 Fischer (R) and (S)
Lowest priority (usually H) comes forward, so assignment
rules are backward!
Clockwise 1-2-3 is (S) and counterclockwise 1-2-3 is (R).
Example:

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 Diastereomers: Cis-Trans
Isomerism on Double Bonds
These stereoisomers are not mirror images of each other,
so they are not enantiomers. They are diastereomers.

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 Diastereomers: Cis-Trans
Isomerism on Rings
Cis-trans isomers are not mirror images, so these are
diastereomers.

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 Diastereomers

Molecules with two or more chiral carbons
Stereoisomers that are not mirror images

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 Two or More Chiral Carbons
When compounds have two or more chiral centers
they have enantiomers, diastereomers, or meso
isomers.
Enantiomers have opposite configurations at each
corresponding chiral carbon.
Diastereomers have some matching and some
opposite configurations.
Meso compounds have internal mirror planes.
Maximum number of isomers is 2n, where n = the
number of chiral carbons.

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 Comparing Structures

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 Meso Compounds

Meso compounds have a plane of symmetry.
If one image is rotated 180°, then it can be superimposed
on the other image.
Meso compounds are achiral even though they have chiral
centers.
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 Absolute and Relative
Configurations
The absolute configuration is the detailed picture
of a molecule, including how the atoms are
arranged in space.
The relative configuration is the experimentally
determined relationship between the configurations
of two molecules, even though we may not know
the absolute configuration of either.

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 Number of Stereoisomers

The 2n rule will not apply to compounds that may have
a plane of symmetry. 2,3-dibromobutane has only three
stereoisomers: (±) diastereomer and the meso
diastereomer.
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 Properties of Diastereomers

Diastereomers have different physical properties, so
they can be easily separated.
Enantiomers differ only in reaction with other chiral
molecules and the direction in which polarized light is
rotated.
Enantiomers are difficult to separate.
Convert enantiomers into diastereomers to be able to
separate them.

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 Diastereomers and Their
Physical Properties

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 Louis Pasteur

In 1848, Louis Pasteur
noticed that a salt of racemic
(±)-tartaric acid crystallizes
into mirror-image crystals.
Using a microscope and a
pair of tweezers, he physically
separated the enantiomeric
crystals.
Pasteur had accomplished the
first artificial resolution of
enantiomers.

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 Chemical Resolution of
Enantiomers

React the racemic mixture with a pure chiral compound, such
as tartaric acid, to form diastereomers, and then separate
them.

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 Formation of (R)- and
(S)-2-Butyl Tartrate

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 Chromatographic
Resolution of Enantiomers

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