9. stereochemistry
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9. Stereochemistry. Based on McMurry’s Organic Chemistry , 6 th edition. Stereochemistry. Some objects are not the same as their mirror images (technically, they have no plane of symmetry) A right-hand glove is different than a left-hand glove (See Figure 9.1) - PowerPoint PPT PresentationTRANSCRIPT
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9. Stereochemistry
Based onMcMurry’s Organic Chemistry, 6th edition
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Stereochemistry Some objects are not the same as their mirror
images (technically, they have no plane of symmetry) A right-hand glove is different than a left-hand
glove (See Figure 9.1) The property is commonly called “handedness”
Organic molecules (including many drugs) have handedness that results from substitution patterns on sp3 hybridized carbon
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Enantiomers – Mirror Images Molecules exist as three-dimensional objects Some molecules are the same as their mirror image Some molecules are different than their mirror image
These are stereoisomers called enantiomers Called chiral molecules Lack a plane of symmetry
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Plane of Symmetry The plane has the same
thing on both sides for the flask
There is no mirror plane for a hand
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Examples of Enantiomers Molecules that have one carbon with 4 different
substituents have a nonsuperimposable mirror image – chiral molecule - pair of enantiomers
But there are chiral molecules that lack this feature
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Mirror-image Forms of Lactic Acid When H and
OH substituents match up, COOH and CH3 don’t
when COOH and CH3 coincide, H and OH don’t
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9.2 The Reason for Handedness: Chirality Molecules that are not superimposable with their
mirror images are chiral (have handedness) A plane of symmetry divides an entire molecule into
two pieces that are exact mirror images A molecule with a plane of symmetry is the same as
its mirror image and is said to be achiral (See Figure 9.4 for examples)
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Chirality If an object has a plane of symmetry it is necessarily
the same as its mirror image The lack of a plane of symmetry is called
“handedness”, chirality Hands, gloves are prime examples of chiral object
They have a “left” and a “right” version
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Chirality Centers A point in a molecule where four different groups (or
atoms) are attached to carbon is called a chirality center There are two nonsuperimposable ways that 4 different
different groups (or atoms) can be attached to one carbon atom If two groups are the same, then there is only one way
A chiral molecule usually has at least one chirality center
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Chirality Centers in Chiral Molecules
Groups are considered “different” if there is any structural variation (if the groups could not be superimposed if detached, they are different)
In cyclic molecules, we compare by following in each direction in a ring
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Interchanging any two substituents on a chirality center converts it to its mirror image.
Only sp3 hybridized C atoms can be chirality centers.
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A pair of enantiomers have identical physical properties except for thedirection in which they rotatethe plane of polarized light.
A single enantiomer is said to be optically active.
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9.3 Optical Activity Light restricted to pass through a plane is plane-
polarized Plane-polarized light that passes through solutions of
achiral compounds remains in that plane Solutions of chiral compounds rotate plane-polarized
light and the molecules are said to be optically active Phenomenon discovered by Biot in the early 19th
century
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A Simple Polarimeter Measures extent of
rotation of plane polarized light
Operator lines up polarizing analyzer and measures angle between incoming and outgoing light
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Optical Activity Light passes through a plane polarizer Plane polarized light is rotated in solutions of optically
active compounds Measured with polarimeter Rotation, in degrees, is [] Clockwise rotation is called dextrorotatory Anti-clockwise is levorotatory
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Measurement of Optical Rotation A polarimeter measures the rotation of plane-
polarized that has passed through a solution The source passes through a polarizer and then is
detected at a second polarizer The angle between the entrance and exit planes is
the optical rotation.
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Specific Rotation To have a basis for comparison, define specific
rotation, []D for an optically active compound []D = observed rotation/(pathlength x concentration)
= /(l x C) = degrees/(dm x g/mL) Specific rotation is that observed for 1 g/mL in
solution in cell with a 10 cm path using light from sodium metal vapor (589 nanometers)
See Table 9.1 for examples
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Specific Rotation and Molecules
Characteristic property of a compound that is optically active – the compound must be chiral
The specific rotation of the enantiomer is equal in magnitude but opposite in sign
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9.4 Pasteur’s Discovery of Enantiomers (1849) Louis Pasteur discovered that sodium ammonium
salts of tartaric acid crystallize into right handed and left handed forms
The optical rotations of equal concentrations of these forms have opposite optical rotations
The solutions contain mirror image isomers, called enantiomers and they crystallized in distinctly different shapes – such an event is rare
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Relative 3-Dimensionl Structure The original method
was a correlation system, classifying related molecules into “families” focused on carbohydrates Correlate to D- and
L-glyceraldehyde D-erythrose is the
mirror image of L-erythrose
This does not apply in general
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9.5 Sequence Rules for Specification of Configuration A general method applies to the configuration at each
chirality center (instead of to the the whole molecule) The configuration is specified by the relative positions
of all the groups with respect to each other at the chirality center
The groups are ranked in an established priority sequence and compared
The relationship of the groups in priority order in space determines the label applied to the configuration, according to a rule
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Sequence Rules (IUPAC)
Assign each group priority according to the Cahn-Ingold-Prelog scheme With the lowest priority group pointing away, look at remaining 3 groups in a plane
Clockwise is designated R (from Latin for “right”)
Counterclockwise is designated S (from Latin word for “left”)
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R-Configuration at Chirality Center Lowest priority group is pointed away and direction of
higher 3 is clockwise, or right turn
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Examples of Applying Sequence Rules If lowest priority is back,
clockwise is R and counterclockwise is S R = Rectus S = Sinister
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9.6 Diastereomers Molecules with more
than one chirality center have mirror image stereoisomers that are enantiomers
In addition they can have stereoisomeric forms that are not mirror images, called diastereomers
See Figure 9-10 2R,3S 2S,3R
2R,3R 2S,3S
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9.7 Meso Compounds Tartaric acid has two chirality centers and two diastereomeric forms One form is chiral and the other is achiral, but both have two chirality
centers An achiral compound with chirality centers is
called a meso compound – it has a plane of symmetry
The two structures on the right in the figure are identical so the compound (2R, 3S) is achiral
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9.8 Molecules with More Than Two Chirality Centers Molecules can have very many chirality centers Each point has two possible permanent
arrangements (R or S), generating two possible stereoisomers
So the number of possible stereoisomers with n chirality centers is 2n
Cholesterol has eight chirality centersMorphine has five (9.17)
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9.9 Physical Properties of Stereoisomers Enantiomeric molecules differ in the direction in which
they rotate plane polarized but their other common physical properties are the same
Daistereomers have a complete set of different common physical properties
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9.10 Racemic Mixtures and Their Resolution A 50:50 mixture of two chiral compounds that are
mirror images does not rotate light – called a racemic mixture (named for “racemic acid” that was the double salt of (+) and (-) tartaric acid
The pure compounds need to be separated ot resolved from the mixture (called a racemate)
To separate components of a racemate (reversibly) we make a derivative of each with a chiral substance that is free of its enantiomer (resolving agent)
This gives diastereomers that are separated by their differing solubility
The resolving agent is then removed
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9.11 A Brief Review of Isomerism
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Constitutional Isomers Different order of connections gives different carbon
backbone and/or different functional groups
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Stereoisomers Same connections, different spatial arrangement of atoms
Enantiomers (nonsuperimposable mirror images) Diastereomers (all other stereoisomers)
Includes cis, trans and configurational
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9.12 Stereochemistry of Reactions: Addition of HBr to Alkenes Many reactions can produce new chirality centers in
compounds. ( 0 1, 1 2, etc.) What is the stereochemistry of the chiral product? What relative amounts of stereoisomers form? Example addition of HBr to 1-butene
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Achiral Intermediate Gives Racemic Product Addition via carbocation Top and bottom are equally accessible
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9.13 Stereochemistry of Reactions: Addition of Br2 to Alkenes Stereospecific
Forms racemic mixture Bromonium ion leads to trans addition
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Addition of Bromine to Trans 2-Butene Gives meso product (both are the same)
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Reaction between two optically inactive (achiral) partners that produces a product with a center of chirality, alwaysleads to an optically inactive product – either racemic or meso.
If you start out with optically inactive reactants, you will end up with optically inactive products.
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Problems 9.20 and 9.21
Draw detailed mechanism andconsider stereochemistry ofaddition of Br2 to cis and trans2-hexene
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9.14 Stereochemistry of Reactions: Addition of HBr to a Chiral Alkene
Gives diastereomers in unequal amounts.
Facial approaches are different in energy
Product is optically active
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As a general rule, reaction of a chiral reactant with an achiral reactant which introduces a new center of chirality, leads to unequal amounts of the distereometric products. If the chiral reactant is optically active the product will also be optically active.
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Problem 9.22 HBr + racemic (+) 4-methyl-1-hexene
Problem 9.23 What products are formed from reaction of HBr with 4-methylcyclopentene
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Chapter 9 Homework
27-30, 32-34, 36-43, 45, 46,48-50, 52, 53, 57, 59, 65-67, 73
Owl for Chapt 9 Nov 18Test on Chapter 9 Nov 20
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9.15 Chirality at Atoms Other Than Carbon Trivalent nitrogen is tetrahedral Does not form a chirality center since it rapidly flips Also applies to phosphorus but it flips more slowly
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9.16 Chirality in Nature Stereoisomers are readily distinguished by chiral
receptors in nature Properties of drugs depend on stereochemistry Think of biological recognition as equivalent to 3-point
interaction See Figure 9-19
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9.17 Prochirality A molecule that is achiral but that can become chiral
by a single alteration is a prochiral molecule
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Prochiral distinctions: faces Planar faces that can become tetrahedral are
different from the top or bottom A center at the planar face at a carbon atom is
designated re if the three groups in priority sequence are clockwise, and si if they are counterclockwise
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Prochiral distinctions, paired atoms or groups An sp3 carbon with two groups that are the same is a
prochirality center The two identical groups are distinguished by
considering either and seeing if it was increased in priority in comparison with the other
If the center becomes R the group is pro-R and pro-S if the center becomes S
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Prochiral Distinctions in Nature Biological reactions often involve making distinctions
between prochiral faces or or groups Chiral entities (such as enzymes) can always make
such a distinction Examples: addition of water to fumarate and
oxidation of ethanol
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