1. Lecture 12 CATALYSIS 2. TRANSFORMATION OF ALKENES AND ALKYNES Copyright ©The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

2. TRANSFORMATION OF ALKENES AND ALKYNES I.METATHESIS OF ALKENES, ALKYNES AND CYCLOALKENES A.Alkene metathesis B.Alkyne metathesis C.ROMP D.Alkyne polymerization II.ALKENE DIMERIZATION AND OLIGOMERIZATION A.Ethylene dimerization B.Oligomerization by successive insertions III.ALKENE ISOMERIZATION A.Double bond migration by  -elimination B.Allylic C-H activation C.Cis-trans isomerization via metallocarbenes IV.OLEFIN POLYMERIZATION

3.  Metathesis – derived from the greek word meaning “to place differently” or “to transpose”  Metal-catalyzed exchange of alkylidene and alkylidyne units in alkenes and alkynes: METATHESIS OF ALKENES AND ALKYNES

4.  Depending on the nature of the applied alkene and the reaction conditions, metathesis reactions can give different results, allowing a structuring of the area: ALKENE METATHESIS

6. ALKENES METATHESIS Chauvin Mechanism (1970) A pathway that involves a metallacyclobutane intermediate A metallacyclobutane intermediate was isolated and characterized by Schrock (1989)

7. ALKENES METATHESIS  A metal alkylidene unit M=CH 2 functions as the catalytically active center  Mo, W, Re, Rh have proven to be particularly useful central metal atoms

8. Early metathesis catalysts were derived from transition metal halides and carbanion donors (WCl 6 / Et 2 Al / EtOH) ALKENE METATHESIS

9. ALKENE METATHESIS - CATALYSTS

10. TRANSFORMATION OF ALKENES AND ALKYNES  Both complexes have low coordination number (CN = 4) allows a facile access to the central metal atom.  Spectator ligands aids (imido, oxo ) in the formation of the metallacycle intermediate

11. CM has been used extensive the industry in the form of Higher Olefin Process (SHOP) – a combination process consisting of oligomerization, isomerization, and metathesis steps. The metathesis step: CROSS METATHESIS (CM)

12.  If a shop process is followed by hydroformylation, fatty alcohols with 8-22 carbon atoms are formed!  In the laboratory, CM has a limited application. Products are obtained as mixtures of Z/E isomers CROSS METATHESIS

13. In contrast to CM, Ring Closing Metathesis (RCM) has become a standard method in organic chemistry. RING-CLOSING METATHESIS

14. Newer catalysts has inspired natural products synthesis: RING CLOSING METATHESIS

15. Assymetric ring closure metathesis (ARCM) has also been developed using chiral catalysts: RING CLOSING METATHESIS

16. Ring-opening metathesis is the reverse of RCM. A cross-metathesis with ethylene forms terminal dienes Ring strain favors ring opening and are specially common with nobornenes and cyclobutenes. Synthetic utility is limited by the formation of different CM and self-methathesis products RING OPENING METATHESIS

17. In some cases selectivity are achieved: RING OPENING METATHESIS

18. Self metathesis; use of open chain alkene substrate is avoided. The C=C double bond in the monomer is conserved in the polymer. The catalytically active species is fixed to the end of the growing chain (“living polymer”) As soon as a certain monomer is consumed, a different monomer can be used to make block coplymers. Can be deactivated by reaction with a carbonyl group to yiled M=O (Wittig reaction). RING OPENING METATHESIS POLYMERIZATION

19. ROMP mechanism: RING OPENING METATHESIS POLYMERIZATION

20. ROMP in the industry: TRANSFORMATION OF ALKENES AND ALKYNES The C=C double bond in this norbornene rubber allows for cross-linking

21. ROMP in the industry: TRANSFORMATION OF ALKENES AND ALKYNES

22. Metathesis involving C C triple bonds can proceed symetrically (Yne YneM) and in the mixed form (Ene YneM) Metathesis using dissymetrical alkynes using MoO 3 or WO 3 as heterogeneous catalysts: ALKYNE METATHESIS

23. Prototype Catalyst: [W(C-tBu)(O-tBu) 3 ] TRANSFORMATION OF ALKENES AND ALKYNES

24. Mechanism: TRANSFORMATION OF ALKENES AND ALKYNES

25. The presence of a double and triple bonds in the reactants presents challenges: selective metathesis TRANSFORMATION OF ALKENES AND ALKYNES

26. Metathesis also applies to nitriles: TRANSFORMATION OF ALKENES AND ALKYNES

27. Mixed (EneYneM): ALKENE – ALKYNE METATHESIS

28. Example:. [Ru(CO) 3 Cl 2 l 2 catalyzes the skeletal rearrangement of 1,6- and 1,7-enynes to form vinylcycloalkenes (Murai, 1994) : ALKENE – ALKYNE METATHESIS

29. SAMPLE PROBLEM: Assume 2-pentene and 2-hexene undergo metathesis. AT equilibrium what are all the possible alkenes that would be present, neglecting stereochemistry about the double bond? Remember to consider self metathesis reactions.

30. SAMPLE PROBLEM: What is the product of cyclooctene metathesis?

31. Two mechanisms: - via metallacyclopentane intermediate - insertion of 2 alkene molecules into M-H ALKENE DIMERIZATION AND OLIGOMERIZATION

32. ALKENE DIMERIZATION VIA METALLACYCLOPENTANE

33. Involves coordination of two ethylene molecules, oxidative coupling, -elimination then reductive elimination. Metal has a low number of valence electron and at least two non-bonding electrons, - necessary for oxidative coupling ALKENE DIMERIZATION AND OLIGOMERIZATION

34. Same as polymerization but limited to insertion of two monomeric olefins into the M-H bond. This system is made catalytic by the - elimination step. Key point: -elimination should be faster than 3 rd alkene insertion. ALKENE DIMERIZATION BY SUCCESSIVE INSERTION

35. Isomerization can occur via migration of the double bond – terminal olefin to an internal olefin. ALKENE ISOMERIZATION

36. ALKENE ISOMERIZATION by  -ELIMINATION  16e hydride complexes isomerize terminal olefins via reversible insertion of the olefin into the M-H bond followed by  - elimination.  Mixture of cis and trans is obtained with the more stable trans form being major.

37. ALKENE ISOMERIZATION by  -ELIMINATION Example:

38. ALKENE ISOMERIZATION by ALLYLIC C-H ACTIVATION Catalyst do not contain a hydride ligand. M should have at least two vacant coordination sites like the 14e species Fe(CO) 3

39. CIS TRANS or Z/E ISOMERIZATION via METALLOCARBENES

40. Ziegler and Natta Polymerization catalyst: TiCl 3 /Et 2 AlCl – a heterogenous mixture Proposed mechanism: (Cosse, 1975) ZIEGLER – NATTA TYPE ALKENE POLYMERIZATION

41. Watson, 1982, DuPont: soluble in initiator, LuCp* 2 CH 3 ZIEGLER – NATTA TYPE ALKENE POLYMERIZATION

48. ALKENE DIMERIZATION AND OLIGOMERIZATION

58. TRANSFORMATION OF ALKENES AND ALKYNES