Transcript Chapter 8
Aromaticity. Reactions of Benzene Chapter 8 Chapter 8 1 Contents of Chapter 15 Aromaticity Heterocyclic Compounds Chemical Consequences of Aromaticity Nomenclature Reactivity Considerations Mechanism for Electrophilic Substitution Halogenation/Nitration/Sulfonation of Benzene Friedel–Crafts Reactions Substituent Effects Retrosynthetic Analysis Chapter 8 2 Aromaticity Benzene is a cyclic compound which has a planar structure with a delocalized cloud of p electrons above and below the plane of the ring Chapter 8 3 Criteria for Aromaticity • There must be an uninterrupted ring of p orbitalbearing atoms leading to a delocalized p cloud For the p cloud to be cyclic, the molecule must be cyclic For the p cloud to be uninterrupted, every ring atom must have a p orbital For the p cloud to form, each p orbital must be able to overlap the p orbital on either side Chapter 8 4 Criteria for Aromaticity • • The p cloud must have an odd number of pairs of p electrons, or (2n+1)•2 = 4n+2 p electrons Hückel’s rule Chapter 8 5 Aromaticity cyclooctatetraene is nonaromatic It is not planar Chapter 8 6 Aromaticity resonance broken nonaromatic 2 p electrons aromatic Chapter 8 4 p electrons antiaromatic 7 Aromaticity Chapter 8 8 Aromaticity The criteria for aromaticity also can be applied to polycyclic hydrocarbons Naphthalene (5 pairs of p electrons), phenanthrene (7 pairs of p electrons), and chrysene (9 pairs of p electrons) all are aromatic Chapter 8 9 Heterocyclic Compounds Lone pair can’t be in p orbital because p orbital used to build p bond with adjacent carbon(s) The lone pair on pyridine’s nitrogen is in an sp2 hybrid, not part of the 3-pair aromatic p system Chapter 8 10 Heterocyclic Compounds In pyrrole the lone pair could be put into either an sp3 hybrid or a p orbital with bonds in sp2 hybrid Pyrrole puts the lone pair in a p orbital, making 3 pairs of p electrons (aromatic is more stable) Chapter 8 11 Heterocyclic Compounds In above structures the N lone pairs could be put into either sp3 hybrids or p orbitals with bonds to N in sp2 hybrids Because the lone pairs give these rings an EVEN number of pi electrons these rings are not aromatic In these cases the lone pairs are put into sp3 hybrid orbitals because nature doesn’t like even numbers of pairs of pi electrons in cyclic pi systems Chapter 8 12 Heterocyclic Compounds In furan and thiophene there are 2 pairs of unshared electrons - one is an sp2 hybrid orbital and one pair is in a p orbital, like pyrrole (3 pairs of p electrons, aromatic) Chapter 8 13 Heterocyclic Compounds Chapter 8 14 Heterocyclic Compounds Quinoline, indole, imidazole, purine, and pyrimidine also are aromatic heterocyclic compounds Chapter 8 15 Chemical Consequences of Aromaticity Chapter 8 16 Chemical Consequences of Aromaticity Cyclopentadiene has such a low pKa because of the stability of the anion formed when the hydrogen ionizes - the anion is aromatic Chapter 8 17 Chemical Consequences of Aromaticity Cycloheptatrienyl bromide is ionic because of the stability of the aromatic cycloheptatrienyl cation Chapter 8 18 Naming Monosubstituted Benzenes Br Cl NO2 bromobenzene chlorobenzene nitrobenzene Chapter 8 C H 2CH 3 ethylbenzene 19 Naming Common Monosubstituted Benzenes OMe anisole CH3 OH NH2 toluene phenol aniline CHO styrene COOH benzaldehyde benzoic acid Chapter 8 CN benzonitrile 20 Reactivity Considerations The benzene ring consists of a ring with p electrons above and below Electrophiles are attracted to a benzene ring and form a nonaromatic carbocation intermediate (a cyclohexadienyl cation) H + Y Y Chapter 8 carbocation intermediate 21 Electrophilic Substitution Electrophilic addition doesn’t occur (would destroy aromaticity) Chapter 8 22 Reactivity Considerations Chapter 8 23 Mechanism for Electrophilic Substitution Reactions Chapter 8 24 Halogenation of Benzene Chapter 8 25 Nitration of Benzene Chapter 8 26 Anilines From Nitrobenzenes • Anilines (aminobenzenes) are always made from nitrobenzenes. • Anilines decompose and make black tar when exposed to electrophilic aromatic substitution (EAS) reaction conditions • For this reason nitrobenzenes are converted to anilines in the very LAST step AFTER all other groups are added by EAS reactions • There are several ways to convert nitrobenzenes to anilines but this course teaches H2 and Pd/C Chapter 8 27 Sulfonation of Benzene Chapter 8 28 Friedel–Crafts Acylation Chapter 8 29 Friedel–Crafts Alkylation Chapter 8 30 Electron-donating Substituents O CH3 O CH3 H 3C H 3C O O O CH3 Resonance contributors increase electron density in ortho and para positions. Overall electron density is bigger. Chapter 8 31 Electron-donating Substituents • A pi system can be considered to be polarized in an alternating fashion by substituents for product analysis purposes. • Electrophiles (+ groups) add to – positions • Alkyl groups and atoms with lone pairs polarize the ring carbon thhey are attached to + Chapter 8 32 Electron-donating Substituents Chapter 8 33 Electron-withdrawing Substituents Atoms with + charge polarize the attached ring carbon negative (–) Chapter 8 34 Electron-withdrawing Substituents Chapter 8 35 Naming Disubstituted Benzenes Chapter 8 36 Naming Disubstituted Benzenes Chapter 8 37 Retrosynthetic Analysis • Work backwards from an aromatic compound to figure out how to make it • First if amino group (NH2) is present work it backwards to nitro (NO2) • Next remove one substituent and polarize the ring according to positions of other substituents • If the substituent you removed came from a – carbon remove another substituent, polarize the ring again, and repeat • If remaining substituents don’t agree on ring polarization or latest removed substituent doesn’t remove from a – carbon replace removed substituent and try to remove another one. • Continue until all substituents have been removed • Reverse the retrosynthetic analysis to figure out what reagents to add to benzene in what order Chapter 8 38 Retrosynthetic Analysis Work out synthesis of 4-bromo-3-chloroaniline using retrosynthetic analysis Chapter 8 39