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Chapter 5 Stereochemistry

Explore the fundamental concepts of stereochemistry, including chirality, enantiomers, and optical activity. Learn about Cahn-Ingold-Prelog Rules, mirror planes of symmetry, and properties of enantiomers. Gain insights into biological discrimination, racemic mixtures, and optical purity calculations, all essential for a comprehensive understanding of molecular structure in organic chemistry.

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Chapter 5 Stereochemistry

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  1. Organic Chemistry, 5th EditionL. G. Wade, Jr. Chapter 5Stereochemistry Jo Blackburn Richland College, Dallas, TX Dallas County Community College District ã 2003,Prentice Hall

  2. Chirality • “Handedness”: right glove doesn’t fit the left hand. • Mirror-image object is different from the original object. => Chapter 5

  3. Stereoisomers • Geometric isomers: cis-trans isomers. • Enantiomers: nonsuperimposable mirror images, different molecules. => trans -1,2-dichlorocyclopentane cis-1,2-dichlorocyclopentane Chapter 5

  4. Chiral Carbons • Tetrahedral carbons with 4 different attached groups are chiral. • Its mirror image will be a different compound (enantiomer). => Chapter 5

  5. Mirror Planes of Symmetry • If two groups are the same, carbon is achiral. (animation) • A molecule with an internal mirror plane cannot be chiral.* Caution! If there is no plane of symmetry, molecule may be chiral or achiral. See if mirror image can be superimposed. => Chapter 5

  6. => (R), (S) Nomenclature • Different molecules (enantiomers) must have different names. • Usually only one enantiomer will be biologically active. • Configuration around the chiral carbon is specified with (R) and (S). Chapter 5

  7. Cahn-Ingold-Prelog Rules • Assign a priority number to each group attached to the chiral carbon. • Atom with highest atomic number assigned the highest priority #1. • In case of ties, look at the next atoms along the chain. • Double and triple bonds are treated like bonds to duplicate atoms. => Chapter 5

  8. expands to 4 => Assign Priorities 2 4 3 3 4 1 2 1 3 1 2 Chapter 5

  9. Assign (R) or (S) • Working in 3D, rotate molecule so that lowest priority group is in back. • Draw an arrow from highest to lowest priority group. • Clockwise = (R), Counterclockwise = (S) => Chapter 5

  10. Properties of Enantiomers • Same boiling point, melting point, density • Same refractive index • Different direction of rotation in polarimeter • Different interaction with other chiral molecules • Enzymes • Taste buds, scent => Chapter 5

  11. Optical Activity • Rotation of plane-polarized light • Enantiomers rotate light in opposite directions, but same number of degrees. => Chapter 5

  12. Polarimetry • Use monochromatic light, usually sodium D • Movable polarizing filter to measure angle • Clockwise = dextrorotatory = d or (+) • Counterclockwise = levorotatory = l or (-) • Not related to (R) and (S) => Chapter 5

  13. (observed) [] = c l c is concentration in g/mL l is length of path in decimeters. => 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. Chapter 5

  14. Calculate []D • A 1.00-g sample is dissolved in 20.0 mL ethanol. 5.00 mL of this solution is placed in a 20.0-cm polarimeter tube at 25C. The observed rotation is 1.25 counterclockwise.=> Chapter 5

  15. Biological Discrimination => Chapter 5

  16. Racemic Mixtures • Equal quantities of d- and l- enantiomers. • Notation: (d,l) or () • No optical activity. • The mixture may have different b.p. and m.p. from the enantiomers! => Chapter 5

  17. Racemic Products If optically inactive reagents combine to form a chiral molecule, a racemic mixture of enantiomers is formed. => Chapter 5

  18. Optical Purity • Also called enantiomeric excess. • Amount of pure enantiomer in excess of the racemic mixture. • If o.p. = 50%, then the observed rotation will be only 50% of the rotation of the pure enantiomer. • Mixture composition would be 75-25. => Chapter 5

  19. 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. => Chapter 5

  20. Chirality of Conformers • If equilibrium exists between two chiral conformers, molecule is not chiral. • Judge chirality by looking at the most symmetrical conformer. • Cyclohexane can be considered to be planar, on average. => Chapter 5

  21. Nonsuperimposable mirror images, but equal energy and interconvertible. Use planar approximation. => Mobile Conformers Chapter 5

  22. Nonmobile Conformers If the conformer is sterically hindered, it may exist as enantiomers. => Chapter 5

  23. => Allene is achiral. Allenes • Chiral compounds with no chiral carbon • Contains sp hybridized carbon with adjacent double bonds: -C=C=C- • End carbons must have different groups. Chapter 5

  24. Fischer Projections • Flat drawing that represents a 3D 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. Chapter 5

  25. Fischer Rules • Carbon chain is on the vertical line. • Highest oxidized carbon at top. • Rotation of 180 in plane doesn’t change molecule. • Do not rotate 90! • Do not turn over out of plane! => Chapter 5

  26. => Fischer Mirror Images • Easy to draw, easy to find enantiomers, easy to find internal mirror planes. • Examples: Chapter 5

  27. (S) => (S) Fischer (R) and (S) • Lowest priority (usually H) comes forward, so assignment rules are backwards! • Clockwise 1-2-3 is (S) and counterclockwise 1-2-3 is (R). • Example: Chapter 5

  28. Diastereomers • Stereoisomers that are not mirror images. • Geometric isomers (cis-trans) • Molecules with 2 or more chiral carbons. => Chapter 5

  29. Alkenes Cis-trans isomers are not mirror images, so these are diastereomers. => Chapter 5

  30. => Ring Compounds • Cis-trans isomers possible. • May also have enantiomers. • Example: trans-1,3-dimethylcylohexane Chapter 5

  31. Two or More Chiral Carbons • Enantiomer? Diastereomer? Meso? Assign (R) or (S) to each chiral carbon. • Enantiomers have opposite configurations at each corresponding chiral carbon. • Diastereomers have some matching, some opposite configurations. • Meso compounds have internal mirror plane. • Maximum number is 2n, where n = the number of chiral carbons. => Chapter 5

  32. => Examples Chapter 5

  33. Fischer-Rosanoff Convention • Before 1951, only relative configurations could be known. • Sugars and amino acids with same relative configuration as (+)-glyceraldehyde were assigned D and same as (-)-glyceraldehyde were assigned L. • With X-ray crystallography, now know absolute configurations: D is (R) and L is (S). • No relationship to dextro- or levorotatory. => Chapter 5

  34. => * * D and L Assignments * Chapter 5

  35. Properties of Diastereomers • Diastereomers have different physical properties: m.p., b.p. • They can be separated easily. • Enantiomers differ only in reaction with other chiral molecules and the direction in which polarized light is rotated. • Enantiomers are difficult to separate.=> Chapter 5

  36. Resolution of Enantiomers React a racemic mixture with a chiral compound to form diastereomers, which can be separated. => Chapter 5

  37. ChromatographicResolution of Enantiomers => Chapter 5

  38. End of Chapter 5 Chapter 5

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