1 / 37

Amines, reactions Amines are similar to ammonia in their reactions.

Amines, reactions Amines are similar to ammonia in their reactions. Like ammonia, amines are basic . Like ammonia, amines are nucleophilic and react with alkyl halides, acid chlorides, and carbonyl compounds. The aromatic amines are highly reactive in electrophilic aromatic substitution.

Download Presentation

Amines, reactions Amines are similar to ammonia in their reactions.

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Amines, reactions Amines are similar to ammonia in their reactions. Like ammonia, amines are basic. Like ammonia, amines are nucleophilic and react with alkyl halides, acid chlorides, and carbonyl compounds. The aromatic amines are highly reactive in electrophilic aromatic substitution.

  2. Amine, reactions: • As bases • Alkylation • Reductive amination • Conversion into amides • EAS • Hofmann elimination from quarternary ammonium salts • Reactions with nitrous acid

  3. As bases • a) with acids • b) relative base strength • c) Kb • d) effect of groups on base strength

  4. with acids

  5. relative base strength RNH2 > NH3 > ArNH2 Kb ionization of the base in water :Base + H2O H:Base+ + OH- Kb = [ H:Base+ ] [ OH- ] / [ :Base ] Kb aliphatic amines 10-3 – 10-4 ammonia 1.8 x 10-5 anilines 10-9 or less

  6. Why are aliphatic amines more basic than ammonia? NH3 + H2O  NH4+ + OH- R-NH2 + H2O  R-NH3+ + OH- The alkyl group, -R, is an electron donating group. The donation of electrons helps to stabilize the ammonium ion by decreasing the positive charge, lowering the ΔH, shifting the ionization farther to the right and increasing the basicity.

  7. Why are aromatic amines less basic than aliphatic amines? R-NH2 + H2O  R-NH3+ + OH- resonance stabilization of the free base, increases the ΔH, shifts the ionization to the left, decreasing base strength.

  8. Effect of substituent groups on base strength: Electron donating groups will stabilize the anilinium ion, decreasing the ΔH, shifting the ionization farther to the right and making the compound a stronger base. Electron withdrawing groups destabilize the anilinium ion, increasing the ΔH, shifting the ionization towards the reactants, making the compound a weaker base.

  9. Common substituent groups: -NH2, -NHR, -NR2 -OH -OR -NHCOCH3 electron donating -C6H5 groups -R -H -X -CHO, -COR -SO3H electron withdrawing -COOH, -COOR groups -CN -NR3+ -NO2

  10. Number the following in decreasing order of base strength (let #1 = most basic, etc. 4 1 5 3 2

  11. 2. Alkylation (ammonolysis of alkyl halides)

  12. 3. Reductive amination

  13. Conversion into amides • R-NH2 + RCOCl  RCONHR + HCl • 1o N-subst. amide • R2NH + RCOCl  RCONR2 + HCl • 2o N,N-disubst. amide • R3N + RCOCl  NR • 3o

  14. Conversion into sulfonamides R-NH2 + ArSO2Cl  ArSO2NHR + HCl 1o N-subst.sulfonamide R2NH + ArSO2Cl  ArSO2NR2 + HCl 2o N,N-disubst.sufonamide R3N + ArSO2Cl  NR

  15. Schotten-Baumann technique: reactions of aromatic acid chlorides are sped up by the addition of base. R-NH2 + ArSO2Cl + KOH  ArSO2NHR 1o acidic ArSO2NR water soluble salt R2NH + ArSO2Cl + KOH  ArSO2NR2 + HCl 2o N,N-disubst.sufonamide water insoluble

  16. Hinsberg Test: unknown amine + benzenesulfonyl chloride, KOH (aq) Reacts to produce a clear solution and then gives a ppt upon acidification  primary amine. Reacts to produce a ppt  secondary amine. Doesn’t react  tertiary amine.

  17. sulfanilamide “magic bullet” antibiotic

  18. EAS • -NH2, -NHR, -NR2 are powerful activating groups and ortho/para directors • a) nitration • b) sulfonation • c) halogenation • d) Friedel-Crafts alkylation • e) Friedel-Crafts acylation • f) coupling with diazonium salts • g) nitrosation

  19. a) nitration

  20. b) sulfonation

  21. c) halogenation

  22. Swimming pool test kit for chlorine:

  23. Friedel-Crafts alkylation • NR with –NH2, -NHR, -NR2

  24. Friedel-Crafts acylation • NR with –NH2, -NHR, -NR2

  25. g) nitrosation

  26. h) coupling with diazonium salts  azo dyes

  27. Hofmann elimination from quarternary hydroxides • step 1, exhaustive methylation  4o salt • step 2, reaction with Ag2O  4o hydroxide + AgX • step 3, heat to eliminate  alkene(s) + R3N

  28. 7. Reactions with nitrous acid

  29. note: 90% of all tested nitrosamines are carcinogenic in man. Many nitrosamine cancers are organ specific. For example, dimethylnitrosamine causes liver cancer while the nitrosamines in tobacco smoke cause lung cancer. Sodium nitrite (“cure”) is used as a preservative in meats such as bacon, bologna, hot dogs, etc. to kill the organism responsible for botulism poisoning. In the stomach, the nitrous acid produced from sodium nitrite can react with secondary and tertiary amines to form nitrosamines. To reduce the formation of nitrosamines, ascorbic acid (Vitamin C) is now added to foods cured with sodium nitrite. Nitrosamines are also found in beer!

  30. Amines, reactions Amines are similar to ammonia in their reactions. Like ammonia, amines are basic. Like ammonia, amines are nucleophilic and react with alkyl halides, acid chlorides, and carbonyl compounds. The aromatic amines are highly reactive in electrophilic aromatic substitution.

  31. Amine, reactions: • As bases • Alkylation • Reductive amination • Conversion into amides • EAS • Hofmann elimination from quarternary ammonium salts • Reactions with nitrous acid

More Related