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Alkenes, Alkynes and Conjugated Dienes

Alkenes, Alkynes and Conjugated Dienes. Alkenes. Introduction—Structure and Bonding. Alkenes are also called olefins. Alkenes contain a carbon—carbon double bond. Terminal alkenes have the double bond at the end of the carbon chain.

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Alkenes, Alkynes and Conjugated Dienes

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  1. Alkenes, Alkynes and Conjugated Dienes

  2. Alkenes Introduction—Structure and Bonding • Alkenes are also called olefins. • Alkenes contain a carbon—carbon double bond. • Terminal alkenes have the double bond at the end of the carbon chain. • Internal alkenes have at least one carbon atom bonded to each end of the double bond. • Cycloalkenes contain a double bond in a ring.

  3. Alkenes Introduction—Structure and Bonding • Recall that the double bond consists of a  bond and a  bond. • Each carbon is sp2 hybridized and trigonal planar, with bond angles of approximately 1200.

  4. Alkenes Introduction—Structure and Bonding • Bond dissociation energies of the C—C bonds in ethane (a  bond only) and ethylene (one  and one  bond) can be used to estimate the strength of the  component of the double bond.

  5. Alkenes Introduction—Structure and Bonding • Cycloalkenes having fewer than eight carbon atoms have a cis geometry. A trans cycloalkene must have a carbon chain long enough to connect the ends of the double bond without introducing too much strain. • trans-Cyclooctene is the smallest isolable trans cycloalkene, but it is considerably less stable than cis-cyclooctene, making it one of the few alkenes having a higher energy trans isomer.

  6. Alkenes Calculating Degrees of Unsaturation • An acyclic alkene has the general structural formula CnH2n • Alkenes are unsaturated hydrocarbons because they have fewer than the maximum number of hydrogen atoms per carbon. • Cycloalkanes also have the general formula CnH2n. • Each  bond or ring removes two hydrogen atoms from a molecule, and this introduces one degree of unsaturation. • The number of degrees of unsaturation for a given molecular formula can be calculated by comparing the actual number of H atoms in a compound and the maximum number of H atoms possible. • This procedure gives the total number of rings and/or  bonds in a molecule.

  7. Alkenes Nomenclature of Alkenes

  8. Alkenes Nomenclature of Alkenes

  9. Alkenes Nomenclature of Alkenes

  10. Alkenes Nomenclature of Alkenes • Some alkene or alkenyl substituents have common names. • The simplest alkene, CH2=CH2, named in the IUPAC system as ethene, is often called ethylene.

  11. Alkenes Physical Properties • Most alkenes exhibit only weak van der Waals interactions, so their physical properties are similar to alkanes of comparable molecular weight. • Alkenes have low melting points and boiling points. • Melting and boiling points increase as the number of carbons increases because of increased surface area. • Alkenes are soluble in organic solvents and insoluble in water. • The C—C single bond between an alkyl group and one of the double bond carbons of an alkene is slightly polar because the sp3 hybridized alkyl carbon donates electron density to the sp2 hybridized alkenyl carbon.

  12. Alkenes Physical Properties • A consequence of this dipole is that cis and trans isomeric alkenes often have somewhat different physical properties. • cis-2-Butene has a higher boiling point (4 0C) than trans-2-butene (1 0C). • In the cis isomer, the two Csp3—Csp2 bond dipoles reinforce each other, yielding a small net molecular dipole. In the trans isomer, the two bond dipoles cancel.

  13. Alkenes Interesting Alkenes

  14. Alkenes Interesting Alkenes

  15. Alkenes Lipids • Triacyl glycerols are hydrolyzed to glycerol and three fatty acids of general structure RCOOH. • As the number of double bonds in the fatty acid increases, the melting point decreases.

  16. Alkenes Lipids • Increasing the number of double bonds in the fatty acid side chains decreases the melting point of the triacylglycerol. • Fats are derived from fatty acids having few or no double bonds. • Oils are derived from fatty acids having a larger number of double bonds. • Saturated fats are typically obtained from animal sources, whereas unsaturated oils are common in vegetable sources. An exception to this generalization is coconut oil, which is largely composed of saturated alkyl side chains.

  17. Alkenes Lipids

  18. Alkenes Lipids

  19. Alkenes Preparation of Alkenes • Alkenes can be prepared from alkyl halides and alcohols via elimination reactions.

  20. Alkenes Introduction to Addition Reactions • The characteristic reaction of alkenes is addition—the  bond is broken and two new  bonds are formed. • Alkenes are electron rich, with the electron density of the  bond concentrated above and below the plane of the molecule. • Because alkenes are electron rich, simple alkenes do not react with nucleophiles or bases, reagents that are themselves electron rich. Alkenes react with electrophiles.

  21. Alkenes Introduction to Addition Reactions • Because the carbon atoms of a double bond are both trigonal planar, the elements of X and Y can be added to them from the same side or from opposite sides.

  22. Alkenes Introduction to Addition Reactions

  23. Alkenes Hydrohalogenation—Electrophilic Addition of HX • Two bonds are broken in this reaction—the weak  bond of the alkene and the HX bond—and two new  bonds are formed—one to H and one to X. • Recall that the H—X bond is polarized, with a partial positive charge on H. Because the electrophilic H end of HX is attracted to the electron-rich double bond, these reactions are called electrophilic additions.

  24. Alkenes Hydrohalogenation—Electrophilic Addition of HX • Addition reactions are exothermic because the two  bonds formed in the product are stronger than the  and  bonds broken in the reactants. For example, H0 for the addition of HBr to ethylene is –14 kcal/mol, as illustrated below.

  25. Alkenes Hydrohalogenation—Electrophilic Addition of HX • The mechanism of electrophilic addition consists of two successive Lewis acid-base reactions. In step 1, the alkene is the Lewis base that donates an electron pair to H—Br, the Lewis acid, while in step 2, Br¯ is the Lewis base that donates an electron pair to the carbocation, the Lewis acid.

  26. Alkenes Hydrohalogenation—Electrophilic Addition of HX • In the representative energy diagram below, each step has its own energy barrier with a transition state energy maximum. Since step 1 has a higher energy transition state, it is rate-determining. H0 for step 1 is positive because more bonds are broken than formed, whereas H0 for step 2 is negative because only bond making occurs.

  27. Alkenes Hydrohalogenation—Markovnikov’s Rule • With an unsymmetrical alkene, HX can add to the double bond to give two constitutional isomers, but only one is actually formed: • This is a specific example of a general trend called Markovnikov’s rule. • Markovnikov’s rule states that in the addition of HX to an unsymmetrical alkene, the H atom bonds to the less substituted carbon atom—that is, the carbon that has the greater number of H atoms to begin with.

  28. Alkenes Hydrohalogenation—Markovnikov’s Rule • The basis of Markovnikov’s rule is the formation of a carbocation in the rate-determining step of the mechanism. • In the addition of HX to an unsymmetrical alkene, the H atom is added to the less substituted carbon to form the more stable, more substituted carbocation.

  29. Alkenes Hydrohalogenation—Markovnikov’s Rule According to the Hammond postulate, Path [2] is preferred because formation of the carbocation is an endothermic process, so the more stable intermediate is formed faster. Path [2] is much faster than Path [1] because the transition state to form the more stable 20 carbocation is lower in energy.

  30. Alkenes Hydrohalogenation—Reaction Stereochemistry • Recall that trigonal planar atoms react with reagents from two directions with equal probability. • Achiral starting materials yield achiral products. • Sometimes new stereogenic centers are formed from hydrohalogenation: A racemic mixture 

  31. Alkenes Hydrohalogenation—Reaction Stereochemistry • The mechanism of hydrohalogenation illustrates why two enantiomers are formed. Initial addition of H+occurs from either side of the planar double bond. • Both modes of addition generate the same achiral carbocation. Either representation of this carbocation can be used to draw the second step of the mechanism.

  32. Alkenes Hydrohalogenation—Reaction Stereochemistry • Nucleophilic attack of Cl¯ on the trigonal planar carbocation also occurs from two different directions, forming two products, A and B, having a new stereogenic center. • A and B are enantiomers. Since attack from either direction occurs with equal probability, a racemic mixture of A and B is formed.

  33. Alkenes Hydrohalogenation—Reaction Stereochemistry • Hydrohalogenation occurs with syn and anti addition of HX. • The terms cis and trans refer to the arrangement of groups in a particular compound, usually an alkene or disubstituted cycloalkene. • The terms syn and anti describe stereochemistry of a process—for example, how two groups are added to a double bond.

  34. Alkenes Hydrohalogenation—Reaction Stereochemistry

  35. Alkenes Hydrohalogenation—Summary

  36. Alkenes Hydration—Electrophilic Addition of Water • Hydration is the addition of water to an alkene to form an alcohol.

  37. Alkenes Hydration—Electrophilic Addition of Water

  38. Alkenes Hydration—Electrophilic Addition of Water • Alcohols add to alkenes, forming ethers by the same mechanism. For example, addition of CH3OH to 2-methylpropene, forms tert-butyl methyl ether (MTBE), a high octane fuel additive. • Note that there are two consequences to the formation of carbocation intermediates: • Markovnikov’s rule holds. • Addition of H and OH occurs in both syn and anti fashion.

  39. Alkenes Halogenation—Addition of Halogen • Halogenation is the addition of X2 (X = Cl or Br) to an alkene to form a vicinal dihalide.

  40. Alkenes Halogenation—Addition of Halogen • Halogens add to  bonds because halogens are polarizable. • The electron rich double bond induces a dipole in an approaching halogen molecule, making one halogen atom electron deficient and the other electron rich. • The electrophilic halogen atom is then attracted to the nucleophilic double bond, making addition possible.

  41. Alkenes Halogenation—Addition of Halogen Carbocations are unstable because they have only six electrons around carbon. Halonium ions are unstable because of ring strain.

  42. Alkenes Halogenation—Reaction Stereochemistry • Consider the chlorination of cyclopentene to afford both enantiomers of trans-1,2-dichlorocyclopentene, with no cis products. • Initial addition of the electrophile Cl+ from (Cl2) occurs from either side of the planar double bond to form a bridged chloronium ion.

  43. Alkenes Halogenation—Reaction Stereochemistry • In the second step, nucleophilic attack of Cl¯ must occur from the backside. • Since the nucleophile attacks from below and the leaving group departs from above, the two Cl atoms in the product are oriented trans to each other. • Backside attack occurs with equal probability at either carbon of the three-membered ring to yield a racemic mixture.

  44. Alkenes Halohydrin Formation Treatment of an alkene with a halogen X2 and H2O forms a halohydrin by addition of the elements of X and OH to the double bond.

  45. Alkenes Halohydrin Formation Even through X¯ is formed in step [1] of the mechanism, its concentration is small compared to H2O (often the solvent), so H2O and not X¯ is the nucleophile.

  46. Oxidations of Alkenes: Syn 1,2-Dihydroxylation • Either OsO4 or KMnO4 will give 1,2 diols (glycols) • Mechanism for Syn Hydroxylation of Alkenes • Cyclic intermediates result from reaction of the oxidized metals • The initial syn addition of the oxygens is preserved when the oxygen-metal bonds are cleaved and the products are syn diols

  47. Oxidative Cleavage of Alkenes • Reaction of an alkene with hot KMnO4 results in cleavage of the double bond and formation of highly oxidized carbons • Unsubstituted carbons become CO2, monosubstituted carbons become carboxylates and disubstituted carbons become ketones • This be used as a chemical test for alkenes in which the purple color of the KMnO4 disappears and forms brown MnO2 residue if alkene (or alkyne) is present

  48. Alkynes An alkyne is a hydrocarbon with one triple bond Acetylene is the simplest alkyne CH CH The IUPAC nomenclature is analogous to alkenes, the suffix for an alkyne is –yne. In the trivial nomenclature acetylene is the parent compound and the groups attached to the sp Carbons are named as substituens on acetylene CH3C CCH2CH3 2-pentyne or ethylmethylacetylene

  49. The Structure of Alkynes A triple bond is composed of a s bond and two p bonds

  50. HC CH H2C CH2 Acetylene Acetylene is a weak acid, but not nearlyas weak as alkanes or alkenes. • Compound pKa • HF 3.2 • H2O 16 • NH3 36 • 45 • CH4 60 26

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