fbpx
Wikipedia

Olefin metathesis

December 15, 2023

In organic chemistry, olefin metathesis is an organic reaction that entails the redistribution of fragments of alkenes (olefins) by the scission and regeneration of carbon-carbon double bonds.[1][2] Because of the relative simplicity of olefin metathesis, it often creates fewer undesired by-products and hazardous wastes than alternative organic reactions. For their elucidation of the reaction mechanism and their discovery of a variety of highly active catalysts, Yves Chauvin, Robert H. Grubbs, and Richard R. Schrock were collectively awarded the 2005 Nobel Prize in Chemistry.[3]

Olefin metathesis
Reaction type Carbon-carbon bond forming reaction
Identifiers
Organic Chemistry Portal olefin-metathesis
RSC ontology ID RXNO:0000280
Reaction scheme of the olefin metathesis - changing groups are colored

Catalysts edit

The reaction requires metal catalysts. Most commercially important processes employ heterogeneous catalysts. The heterogeneous catalysts are often prepared by in-situ activation of a metal halide (MClx) using organoaluminium or organotin compounds, e.g. combining MClx–EtAlCl2. A typical catalyst support is alumina. Commercial catalysts are often based on molybdenum and ruthenium. Well-defined organometallic compounds have mainly been investigated for small-scale reactions or in academic research. The homogeneous catalysts are often classified as Schrock catalysts and Grubbs catalysts. Schrock catalysts feature molybdenum(VI)- and tungsten(VI)-based centers supported by alkoxide and imido ligands.[4]

 
Commercially available schrock catalysts

Grubbs catalysts, on the other hand, are ruthenium(II) carbenoid complexes.[5] Many variations of Grubbs catalysts are known. Some have been modified with a chelating isopropoxybenzylidene ligand to form the related Hoveyda–Grubbs catalyst.

 
Common Grubbs catalysts

Applications edit

Olefin metathesis has several industrial applications. Almost all commercial applications employ heterogeneous catalysts using catalysts developed well before the Nobel-Prize winning work on homogeneous complexes.[6] Representative processes include:[1]

  • The Phillips Triolefin and the Olefin conversion technology. This process interconverts propylene with ethylene and 2-butenes. Rhenium and molybdenum catalysts are used. Nowadays, only the reverse reaction, i.e., the conversion of ethylene and 2-butene to propylene is industrially practiced, however.[6]
  • Shell higher olefin process (SHOP) produces (alpha-olefins) for conversion to detergents. The process recycles certain olefin fractions using metathesis.[7]
  • Neohexene production, which involves ethenolysis of isobutene dimers. The catalyst is derived from tungsten trioxide supported on silica and MgO.
  • 1,5-Hexadiene and 1,9-decadiene, useful crosslinking agents and synthetic intermediates, are produced commercially by ethenolysis of 1,5-cyclooctadiene and cyclooctene. The catalyst is derived from Re2O7 on alumina.
  • Synthesis of pharmaceutical drugs,[8]

Homogeneous catalyst potential edit

Molecular catalysts have been explored for the preparation of a variety of potential applications.[9] the manufacturing of high-strength materials, the preparation of cancer-targeting nanoparticles,[10] and the conversion of renewable plant-based feedstocks into hair and skin care products.[11]

Types edit

Some important classes of olefin metathesis include:

Mechanism edit

Hérisson and Chauvin first proposed the widely accepted mechanism of transition metal alkene metathesis.[12] The direct [2+2] cycloaddition of two alkenes is formally symmetry forbidden and thus has a high activation energy. The Chauvin mechanism involves the [2+2] cycloaddition of an alkene double bond to a transition metal alkylidene to form a metallacyclobutane intermediate. The metallacyclobutane produced can then cycloeliminate to give either the original species or a new alkene and alkylidene. Interaction with the d-orbitals on the metal catalyst lowers the activation energy enough that the reaction can proceed rapidly at modest temperatures.

 
Olefin metathesis mechanism

Olefin metathesis involves little change in enthalpy for unstrained alkenes. Product distributions are determined instead by le Chatelier's Principle, i.e. entropy.

 
Classification of Olefin metathesis reactions

Cross metathesis and ring-closing metathesis are driven by the entropically favored evolution of ethylene or propylene, which can be removed from the system because they are gases. Because of this CM and RCM reactions often use alpha-olefins. The reverse reaction of CM of two alpha-olefins, ethenolysis, can be favored but requires high pressures of ethylene to increase ethylene concentration in solution. The reverse reaction of RCM, ring-opening metathesis, can likewise be favored by a large excess of an alpha-olefin, often styrene. Ring-opening metathesis usually involves a strained alkene (often a norbornene) and the release of ring strain drives the reaction. Ring-closing metathesis, conversely, usually involves the formation of a five- or six-membered ring, which is enthalpically favorable; although these reactions tend to also evolve ethylene, as previously discussed. RCM has been used to close larger macrocycles, in which case the reaction may be kinetically controlled by running the reaction at high dilutions.[13] The same substrates that undergo RCM can undergo acyclic diene metathesis, with ADMET favored at high concentrations. The Thorpe–Ingold effect may also be exploited to improve both reaction rates and product selectivity.

Cross-metathesis is synthetically equivalent to (and has replaced) a procedure of ozonolysis of an alkene to two ketone fragments followed by the reaction of one of them with a Wittig reagent.

Historical overview edit

"Olefin metathesis is a child of industry and, as with many catalytic processes, it was discovered by accident."[1] As part of ongoing work in what would later become known as Ziegler–Natta catalysis Karl Ziegler discovered the conversion of ethylene into 1-butene instead of a saturated long-chain hydrocarbon (see nickel effect).[14]

In 1960 a Du Pont research group polymerized norbornene to polynorbornene using lithium aluminum tetraheptyl and titanium tetrachloride[15] (a patent by this company on this topic dates back to 1955[16]),

 

a reaction then classified as a so-called coordination polymerization. According to the then proposed reaction mechanism a RTiX titanium intermediate first coordinates to the double bond in a pi complex. The second step then is a concerted SNi reaction breaking a CC bond and forming a new alkylidene-titanium bond; the process then repeats itself with a second monomer:

 

Only much later the polynorbornene was going to be produced through ring opening metathesis polymerisation. The DuPont work was led by Herbert S. Eleuterio. Giulio Natta in 1964 also observed the formation of an unsaturated polymer when polymerizing cyclopentene with tungsten and molybdenum halides.[17]

In a third development leading up to olefin metathesis, researchers at Phillips Petroleum Company in 1964[18] described olefin disproportionation with catalysts molybdenum hexacarbonyl, tungsten hexacarbonyl, and molybdenum oxide supported on alumina for example converting propylene to an equal mixture of ethylene and 2-butene for which they proposed a reaction mechanism involving a cyclobutane (they called it a quasicyclobutane) – metal complex:

 

This particular mechanism is symmetry forbidden based on the Woodward–Hoffmann rules first formulated two years earlier. Cyclobutanes have also never been identified in metathesis reactions, which is another reason why it was quickly abandoned.

Then in 1967 researchers led by Nissim Calderon at the Goodyear Tire and Rubber Company described a novel catalyst system for the metathesis of 2-pentene based on tungsten hexachloride, ethanol, and the organoaluminum compound EtAlMe2. The researchers proposed a name for this reaction type: olefin metathesis.[19] Formerly the reaction had been called "olefin disproportionation."

 

In this reaction 2-pentene forms a rapid (a matter of seconds) chemical equilibrium with 2-butene and 3-hexene. No double bond migrations are observed; the reaction can be started with the butene and hexene as well and the reaction can be stopped by addition of methanol.

The Goodyear group demonstrated that the reaction of regular 2-butene with its all-deuterated isotopologue yielded C4H4D4 with deuterium evenly distributed.[20] In this way they were able to differentiate between a transalkylidenation mechanism and a transalkylation mechanism (ruled out):

 

In 1971 Chauvin proposed a four-membered metallacycle intermediate to explain the statistical distribution of products found in certain metathesis reactions.[21] This mechanism is today considered the actual mechanism taking place in olefin metathesis.

 

Chauvin's experimental evidence was based on the reaction of cyclopentene and 2-pentene with the homogeneous catalyst tungsten(VI) oxytetrachloride and tetrabutyltin:

 

The three principal products C9, C10 and C11 are found in a 1:2:1 regardless of conversion. The same ratio is found with the higher oligomers. Chauvin also explained how the carbene forms in the first place: by alpha-hydride elimination from a carbon metal single bond. For example, propylene (C3) forms in a reaction of 2-butene (C4) with tungsten hexachloride and tetramethyltin (C1).

In the same year Pettit who synthesised cyclobutadiene a few years earlier independently came up with a competing mechanism.[22] It consisted of a tetramethylene intermediate with sp3 hybridized carbon atoms linked to a central metal atom with multiple three-center two-electron bonds.

 

Experimental support offered by Pettit for this mechanism was based on an observed reaction inhibition by carbon monoxide in certain metathesis reactions of 4-nonene with a tungsten metal carbonyl[23]

Robert H. Grubbs got involved in metathesis in 1972 and also proposed a metallacycle intermediate but one with four carbon atoms in the ring.[24] The group he worked in reacted 1,4-dilithiobutane with tungsten hexachloride in an attempt to directly produce a cyclomethylenemetallacycle producing an intermediate, which yielded products identical with those produced by the intermediate in the olefin metathesis reaction. This mechanism is pairwise:

 

In 1973 Grubbs found further evidence for this mechanism by isolating one such metallacycle not with tungsten but with platinum by reaction of the dilithiobutane with cis-bis(triphenylphosphine)dichloroplatinum(II)[25]

In 1975 Katz also arrived at a metallacyclobutane intermediate consistent with the one proposed by Chauvin[26] He reacted a mixture of cyclooctene, 2-butene and 4-octene with a molybdenum catalyst and observed that the unsymmetrical C14 hydrocarbon reaction product is present right from the start at low conversion.

 

In any of the pairwise mechanisms with olefin pairing as rate-determining step this compound, a secondary reaction product of C12 with C6, would form well after formation of the two primary reaction products C12 and C16.

In 1974 Casey was the first to implement carbenes into the metathesis reaction mechanism:[27]

 

Grubbs in 1976 provided evidence against his own updated pairwise mechanism:

 

with a 5-membered cycle in another round of isotope labeling studies in favor of the 4-membered cycle Chauvin mechanism:[28][29]

 

In this reaction the ethylene product distribution   at low conversion was found to be consistent with the carbene mechanism. On the other hand, Grubbs did not rule out the possibility of a tetramethylene intermediate.

The first practical metathesis system was introduced in 1978 by Tebbe based on the (what later became known as the) Tebbe reagent.[30] In a model reaction isotopically labeled carbon atoms in isobutene and methylenecyclohexane switched places:

 

The Grubbs group then isolated the proposed metallacyclobutane intermediate in 1980 also with this reagent together with 3-methyl-1-butene:[31]

 

They isolated a similar compound in the total synthesis of capnellene in 1986:[32]

 

In that same year the Grubbs group proved that metathesis polymerization of norbornene by Tebbe's reagent is a living polymerization system[33] and a year later Grubbs and Schrock co-published an article describing living polymerization with a tungsten carbene complex[34] While Schrock focussed his research on tungsten and molybdenum catalysts for olefin metathesis, Grubbs started the development of catalysts based on ruthenium, which proved to be less sensitive to oxygen and water and therefore more functional group tolerant.

Grubbs catalysts edit

In the 1960s and 1970s various groups reported the ring-opening polymerization of norbornene catalyzed by hydrated trichlorides of ruthenium and other late transition metals in polar, protic solvents.[35][36][37] This prompted Robert H. Grubbs and coworkers to search for well-defined, functional group tolerant catalysts based on ruthenium. The Grubbs group successfully polymerized the 7-oxo norbornene derivative using ruthenium trichloride, osmium trichloride as well as tungsten alkylidenes.[38] They identified a Ru(II) carbene as an effective metal center and in 1992 published the first well-defined, ruthenium-based olefin metathesis catalyst, (PPh3)2Cl2Ru=CHCH=CPh2:[39]

 

The corresponding tricyclohexylphosphine complex (PCy3)2Cl2Ru=CHCH=CPh2 was also shown to be active.[40] This work culminated in the now commercially available 1st generation Grubbs catalyst.[41][42]

Schrock catalysts edit

Schrock entered the olefin metathesis field in 1979 as an extension of work on tantalum alkylidenes.[43] The initial result was disappointing as reaction of CpTa(=CH−t−Bu)Cl2 with ethylene yielded only a metallacyclopentane, not metathesis products:[44]

 

But by tweaking this structure to a PR3Ta(CHt−bu)(Ot−bu)2Cl (replacing chloride by t-butoxide and a cyclopentadienyl by an organophosphine, metathesis was established with cis-2-pentene.[45] In another development, certain tungsten oxo complexes of the type W(O)(CHt−Bu)(Cl)2(PEt)3 were also found to be effective.[46]

Schrock alkylidenes for olefin metathesis of the type Mo(NAr)(CHC(CH3)2R){OC(CH3)(CF3)2}2 were commercialized starting in 1990.[47][48]

 

The first asymmetric catalyst followed in 1993[49]

 

With a Schrock catalyst modified with a BINOL ligand in a norbornadiene ROMP leading to highly stereoregular cis, isotactic polymer.

See also edit

References edit

  1. ^ a b c Lionel Delaude; Alfred F. Noels (2005). "Metathesis". Kirk-Othmer Encyclopedia of Chemical Technology. Weinheim: Wiley-VCH. doi:10.1002/0471238961.metanoel.a01. ISBN 978-0-471-23896-6.
  2. ^ Astruc D. (2005). "The metathesis reactions: from a historical perspective to recent developments". New Journal of Chemistry. 29 (1): 42–56. doi:10.1039/b412198h. S2CID 98046245.
  3. ^ "The Nobel Prize in Chemistry 2005" (Press release). Nobelprize.org. 5 October 2005.
  4. ^ R.R. Schrock (1986). "High-oxidation-state molybdenum and tungsten alkylidene complexes". Accounts of Chemical Research. 19 (11): 342–348. doi:10.1021/ar00131a003.
  5. ^ Ileana Dragutan; Valerian Dragutan; Petru Filip (2005). . Arkivoc: 105–129. Archived from the original on 12 May 2006. Retrieved 6 October 2005.
  6. ^ a b Ghashghaee, Mohammad (2018). "Heterogeneous catalysts for gas-phase conversion of ethylene to higher olefins". Reviews in Chemical Engineering. 34 (5): 595–655. doi:10.1515/revce-2017-0003. S2CID 103664623.
  7. ^ Klaus Weissermel, Hans-Jurgen Arpe (1997). Industrial Organic Chemistry (3rd ed.). John Wiley & Sons. ISBN 3-527-28838-4.
  8. ^ McCauley JA, McIntyre CJ, Rudd MT, Nguyen KT, Romano JJ, Butcher JW, Gilbert KF, Bush KJ, Holloway MK, Swestock J, Wan BL, Carroll SS, DiMuzio JM, Graham DJ, Ludmerer SW, Mao SS, Stahlhut MW, Fandozzi CM, Trainor N, Olsen DB, Vacca JP, Liverton NJ (March 2010). "Discovery of vaniprevir (MK-7009), a macrocyclic hepatitis C virus NS3/4a protease inhibitor". Journal of Medicinal Chemistry. 53 (6): 2443–63. doi:10.1021/jm9015526. PMID 20163176.
  9. ^ Kotha, S; Waghule GT (June 2012). "Diversity Oriented Approach to Crownophanes by Enyne Metathesis and Diels–Alder Reaction as Key Steps". The Journal of Organic Chemistry. 77 (14): 6314–6318. doi:10.1021/jo300766f. PMID 22731677.
  10. ^ Matson JB, Grubbs RH (2008). "Synthesis of Fluorine-18 Functionalized Nanoparticles for use as in vivo Molecular Imaging Agents" (PDF). Journal of the American Chemical Society. 130 (21): 6731–6733. doi:10.1021/ja802010d. PMID 18452296.
  11. ^ (Press release). Elevance Renewable Sciences. 9 September 2008. Archived from the original on 9 December 2011. Retrieved 19 January 2012.
  12. ^ Jean-Louis Hérisson, Par; Chauvin, Yves (1971). "Catalyse de transformation des oléfines par les complexes du tungstène. II. Télomérisation des oléfines cycliques en présence d'oléfines acycliques". Die Makromolekulare Chemie (in French). 141 (1): 161–176. doi:10.1002/macp.1971.021410112.
  13. ^ Sambasivarao Kotha; Kuldeep Singh (2007). "Cross-enyne and ring-closing metathesis cascade: A building-block approach suitable for diversity-oriented synthesis of densely functionalized macroheterocycles with amino acid scaffolds". European Journal of Organic Chemistry. 2007 (35): 5909–5916. doi:10.1002/ejoc.200700744.
  14. ^ Ziegler, Karl; Holzkamp, E.; Breil, H.; Martin, H. (1955). "Polymerisation von Äthylen und anderen Olefinen". Angewandte Chemie. 67 (16): 426. Bibcode:1955AngCh..67..426Z. doi:10.1002/ange.19550671610.
  15. ^ Truett, W. L.; Johnson, D. R.; Robinson, I. M.; Montague, B. A. (1960). "Polynorbornene by Coördination Polymerization". Journal of the American Chemical Society. 82 (9): 2337–2340. doi:10.1021/ja01494a057.
  16. ^ A. W. Anderson and N. G. Merckling, U. S. U.S. Patent 2,721,189 (18 October 1955)
  17. ^ Natta, G.; Dall'asta, G.; Mazzanti, G. (1964). "Stereospecific Homopolymerization of Cyclopentene". Angewandte Chemie International Edition in English. 3 (11): 723–729. doi:10.1002/anie.196407231.
  18. ^ Banks, R. L.; Bailey, G. C. (1964). "Olefin Disproportionation. A New Catalytic Process". Industrial & Engineering Chemistry Product Research and Development. 3 (3): 170–173. doi:10.1021/i360011a002.
  19. ^ Calderon, N; Chen, Hung Yu; Scott, Kenneth W. (1967). "Olefin metathesis – A novel reaction for skeletal transformations of unsaturated hydrocarbons". Tetrahedron Letters. 8 (34): 3327–3329. doi:10.1016/S0040-4039(01)89881-6.
  20. ^ Calderon, Nissim.; Ofstead, Eilert A.; Ward, John P.; Judy, W. Allen.; Scott, Kenneth W. (1968). "Olefin metathesis. I. Acyclic vinylenic hydrocarbons". Journal of the American Chemical Society. 90 (15): 4133–4140. doi:10.1021/ja01017a039.
  21. ^ Jean-Louis Hérisson, Par; Chauvin, Yves (1971). "Catalyse de transformation des oléfines par les complexes du tungstène. II. Télomérisation des oléfines cycliques en présence d'oléfines acycliques". Die Makromolekulare Chemie. 141 (1): 161–176. doi:10.1002/macp.1971.021410112.
  22. ^ S. Lewandos, G; Pettit, R. (1971). "A proposed mechanism for the metal-catalysed disproportionation reaction of olefins". Tetrahedron Letters. 12 (11): 789–793. doi:10.1016/S0040-4039(01)96558-X.
  23. ^ Lewandos, Glenn S.; Pettit, R. (1971). "Mechanism of the metal-catalyzed disproportionation of olefins". Journal of the American Chemical Society. 93 (25): 7087–7088. doi:10.1021/ja00754a067.
  24. ^ Grubbs, Robert H.; Brunck, Terence K. (1972). "Possible intermediate in the tungsten-catalyzed olefin metathesis reaction". Journal of the American Chemical Society. 94 (7): 2538–2540. doi:10.1021/ja00762a073.
  25. ^ Biefeld, Carol G.; Eick, Harry A.; Grubbs, Robert H. (1973). "Crystal structure of bis(triphenylphosphine)tetramethyleneplatinum(II)". Inorganic Chemistry. 12 (9): 2166–2170. doi:10.1021/ic50127a046.
  26. ^ Katz, Thomas J.; McGinnis, James (1975). "Mechanism of the olefin metathesis reaction". Journal of the American Chemical Society. 97 (6): 1592–1594. doi:10.1021/ja00839a063.
  27. ^ Casey, Charles P.; Burkhardt, Terry J. (1974). "Reactions of (diphenylcarbene)pentacarbonyltungsten(0) with alkenes. Role of metal-carbene complexes in cyclopropanation and olefin metathesis reactions". Journal of the American Chemical Society. 96 (25): 7808–7809. doi:10.1021/ja00832a032.
  28. ^ Grubbs, Robert H.; Burk, Patrick L.; Carr, Dale D. (1975). "Mechanism of the olefin metathesis reaction". Journal of the American Chemical Society. 97 (11): 3265–3267. doi:10.1021/ja00844a082.
  29. ^ Grubbs, Robert H.; Carr, D. D.; Hoppin, C.; Burk, P. L. (1976). "Consideration of the mechanism of the metal catalyzed olefin metathesis reaction". Journal of the American Chemical Society. 98 (12): 3478–3483. doi:10.1021/ja00428a015.
  30. ^ Tebbe, F. N.; Parshall, G. W.; Reddy, G. S. (1978). "Olefin homologation with titanium methylene compounds". Journal of the American Chemical Society. 100 (11): 3611–3613. doi:10.1021/ja00479a061.
  31. ^ Howard, T. R.; Lee, J. B.; Grubbs, R. H. (1980). "Titanium metallacarbene-metallacyclobutane reactions: stepwise metathesis". Journal of the American Chemical Society. 102 (22): 6876–6878. doi:10.1021/ja00542a050.
  32. ^ Stille, John R.; Grubbs, Robert H. (1986). "Synthesis of (.+-.)-.DELTA.9,12-capnellene using titanium reagents". Journal of the American Chemical Society. 108 (4): 855–856. doi:10.1021/ja00264a058.
  33. ^ Gilliom, Laura R.; Grubbs, Robert H. (1986). "Titanacyclobutanes derived from strained, cyclic olefins: the living polymerization of norbornene". Journal of the American Chemical Society. 108 (4): 733–742. doi:10.1021/ja00264a027.
  34. ^ Schrock, R. R.; Feldman, J.; Cannizzo, L. F.; Grubbs, R. H. (1987). "Ring-opening polymerization of norbornene by a living tungsten alkylidene complex". Macromolecules. 20 (5): 1169–1172. Bibcode:1987MaMol..20.1169S. doi:10.1021/ma00171a053.
  35. ^ Michelotti, Francis W.; Keaveney, William P. (1965). "Coordinated Polymerization of the Bicyclo-(2.2.1)-heptene-2 Ring System (Norbornene) in Polar Media". Journal of Polymer Science Part A: General Papers. 3 (3): 895–905. doi:10.1002/pol.1965.100030305.
  36. ^ Rinehart, Robert E.; Smith, Homer P. (1965). "The Emulsion Polymerization of the Norbornene Ring System Catalyzed by Noble Metal Compounds". Journal of Polymer Science Part B: Polymer Letters. 3 (12): 1049–1052. Bibcode:1965JPoSL...3.1049R. doi:10.1002/pol.1965.110031215.
  37. ^ Porri, Lido; Rossi, Renzo; Diversi, Pietro; Lucherini, Antonio (1974). "Ring-Opening Polymerization of Cycloolefins with Catalysts Derived from Ruthenium and Iridium". Die Makromolekulare Chemie. 175 (11): 3097–3115. doi:10.1002/macp.1974.021751106.
  38. ^ Novak, Bruce M.; Grubbs, Robert H. (1988). "The ring opening metathesis polymerization of 7-oxabicyclo[2.2.1]hept-5-ene derivatives: a new acyclic polymeric ionophore". Journal of the American Chemical Society. 110 (3): 960–961. doi:10.1021/ja00211a043.
  39. ^ Nguyen, Sonbinh T.; Johnson, Lynda K.; Grubbs, Robert H.; Ziller, Joseph W. (1992). "Ring-opening metathesis polymerization (ROMP) of norbornene by a Group VIII carbene complex in protic media" (PDF). Journal of the American Chemical Society. 114 (10): 3974–3975. doi:10.1021/ja00036a053.
  40. ^ Nguyen, Sonbinh T.; Grubbs, Robert H.; Ziller, Joseph W. (1993). "Syntheses and activities of new single-component, ruthenium-based olefin metathesis catalysts". Journal of the American Chemical Society. 115 (21): 9858–9859. doi:10.1021/ja00074a086.
  41. ^ Schwab, Peter; France, Marcia B.; Ziller, Joseph W.; Grubbs, Robert H. (1995). "A Series of Well-Defined Metathesis Catalysts–Synthesis of [RuCl2(CHR′)(PR3)2] and Its Reactions". Angewandte Chemie International Edition in English. 34 (18): 2039–2041. doi:10.1002/anie.199520391.
  42. ^ Schwab, Peter; Grubbs, Robert H.; Ziller, Joseph W. (1996). "Synthesis and Applications of RuCl2(=CHR')(PR3)2: The Influence of the Alkylidene Moiety on Metathesis Activity". Journal of the American Chemical Society. 118: 100–110. doi:10.1021/ja952676d.
  43. ^ Schrock, R. R.; Meakin, P. (1974). "Pentamethyl complexes of niobium and tantalum". Journal of the American Chemical Society. 96 (16): 5288–5290. doi:10.1021/ja00823a064.
  44. ^ McLain, S. J.; Wood, C. D.; Schrock, R. R. (1979). "Preparation and characterization of tantalum(III) olefin complexes and tantalum(V) metallacyclopentane complexes made from acyclic α olefins". Journal of the American Chemical Society. 101 (16): 4558–4570. doi:10.1021/ja00510a022.
  45. ^ Schrock, R; Rocklage, Scott; Wengrovius, Jeffrey; Rupprecht, Gregory; Fellmann, Jere (1980). "Preparation and characterization of active niobium, tantalum and tungsten metathesis catalysts". Journal of Molecular Catalysis. 8 (1–3): 73–83. doi:10.1016/0304-5102(80)87006-4.
  46. ^ Wengrovius, Jeffrey H.; Schrock, Richard R.; Churchill, Melvyn Rowen; Missert, Joseph R.; Youngs, Wiley J. (1980). "Multiple metal-carbon bonds. 16. Tungsten-oxo alkylidene complexes as olefins metathesis catalysts and the crystal structure of W(O)(CHCMe3(PEt3)Cl2". Journal of the American Chemical Society. 102 (13): 4515–4CF6. doi:10.1021/ja00533a035.
  47. ^ Schrock, Richard R.; Murdzek, John S.; Bazan, Gui C.; Robbins, Jennifer; Dimare, Marcello; O'Regan, Marie (1990). "Synthesis of molybdenum imido alkylidene complexes and some reactions involving acyclic olefins". Journal of the American Chemical Society. 112 (10): 3875–3886. doi:10.1021/ja00166a023.
  48. ^ Bazan, Guillermo C.; Oskam, John H.; Cho, Hyun Nam; Park, Lee Y.; Schrock, Richard R. (1991). "Living Ring-Opening Metathesis Polymerization of 2,3-Difunctionalized 7-Oxanorbornenes and 7-Oxanorbornadienes by Mo(CHCMe2R)(N-2,6-C6H3-i-Pr2)(O-t-Bu)2 and Mo(CHCMe2R)(N-2,6-C6H3-i-Pr2)(OCMe2CF3)2". 113 (18): 6899–6907. doi:10.1021/ja00018a028. {{cite journal}}: Cite journal requires |journal= (help)
  49. ^ McConville, David H.; Wolf, Jennifer R.; Schrock, Richard R. (1993). "Synthesis of chiral molybdenum ROMP initiators and all-cis highly tactic poly(2,3-(R)2norbornadiene) (R = CF3 or CO2Me)". Journal of the American Chemical Society. 115 (10): 4413–4414. doi:10.1021/ja00063a090.

Further reading edit

  1. "Olefin Metathesis: Big-Deal Reaction". 80 (51). 2002: 29–33. doi:10.1021/cen-v080n016.p029. {{cite journal}}: Cite journal requires |journal= (help)
  2. "Olefin Metathesis: The Early Days". 80 (51). 2002: 34–38. doi:10.1021/cen-v080n029.p034. {{cite journal}}: Cite journal requires |journal= (help)
  3. Schrock, R. R. (1990). "Living ring-opening metathesis polymerization catalyzed by well-characterized transition-metal alkylidene complexes". Accounts of Chemical Research. 23 (5): 158–165. doi:10.1021/ar00173a007.
  4. Schrock, R. R.; Hoveyda, A. H. (2003). "Molybdenum and Tungsten Imido Alkylidene Complexes as Efficient Olefin-Metathesis Catalysts". Angewandte Chemie International Edition. 42 (38): 4592–4633. doi:10.1002/anie.200300576. PMID 14533149. S2CID 35370749.
  5. Samojłowicz, C.; Grela, K. (2009). "Ruthenium-Based Olefin Metathesis Catalysts Bearing N-Heterocyclic Carbene Ligands". Chemical Reviews. 109 (8): 3708–3742. doi:10.1021/cr800524f. PMID 19534492.
  6. Vougioukalakis, G. C.; Grubbs, R. H. (2010). "Ruthenium-Based Heterocyclic Carbene-Coordinated Olefin Metathesis Catalysts". Chemical Reviews. 110 (3): 1746–1787. doi:10.1021/cr9002424. PMID 20000700. S2CID 4589661.
  7. Trnka, T. M.; Grubbs, R. H. (2001). "The Development of L2X2Ru=CHR Olefin Metathesis Catalysts: An Organometallic Success Story". Accounts of Chemical Research. 34 (1): 18–29. doi:10.1021/ar000114f. PMID 11170353. S2CID 22145255.
  8. Grubbs, R. H.; Chang, S. (1998). "Recent advances in olefin metathesis and its application in organic synthesis". Tetrahedron. 54 (18): 4413–4450. doi:10.1016/S0040-4020(97)10427-6.
  9. Grubbs, R. H. (2004). "Olefin metathesis". Tetrahedron. 60 (34): 7117–7140. doi:10.1016/j.tet.2004.05.124.
  10. Grela, K. (2010). Grela, K. (ed.). "Progress in metathesis chemistry (Editorial for Open Access Thematic Series)". Beilstein Journal of Organic Chemistry. 6: 1089–1090. doi:10.3762/bjoc.6.124. PMC 3002079. PMID 21160917.

December 15, 2023
olefin, metathesis, organic, chemistry, olefin, metathesis, organic, reaction, that, entails, redistribution, fragments, alkenes, olefins, scission, regeneration, carbon, carbon, double, bonds, because, relative, simplicity, olefin, metathesis, often, creates,. In organic chemistry olefin metathesis is an organic reaction that entails the redistribution of fragments of alkenes olefins by the scission and regeneration of carbon carbon double bonds 1 2 Because of the relative simplicity of olefin metathesis it often creates fewer undesired by products and hazardous wastes than alternative organic reactions For their elucidation of the reaction mechanism and their discovery of a variety of highly active catalysts Yves Chauvin Robert H Grubbs and Richard R Schrock were collectively awarded the 2005 Nobel Prize in Chemistry 3 Olefin metathesisReaction type Carbon carbon bond forming reactionIdentifiersOrganic Chemistry Portal olefin metathesisRSC ontology ID RXNO 0000280Reaction scheme of the olefin metathesis changing groups are colored Contents 1 Catalysts 2 Applications 2 1 Homogeneous catalyst potential 3 Types 4 Mechanism 5 Historical overview 5 1 Grubbs catalysts 5 2 Schrock catalysts 6 See also 7 References 8 Further readingCatalysts editThe reaction requires metal catalysts Most commercially important processes employ heterogeneous catalysts The heterogeneous catalysts are often prepared by in situ activation of a metal halide MClx using organoaluminium or organotin compounds e g combining MClx EtAlCl2 A typical catalyst support is alumina Commercial catalysts are often based on molybdenum and ruthenium Well defined organometallic compounds have mainly been investigated for small scale reactions or in academic research The homogeneous catalysts are often classified as Schrock catalysts and Grubbs catalysts Schrock catalysts feature molybdenum VI and tungsten VI based centers supported by alkoxide and imido ligands 4 nbsp Commercially available schrock catalystsGrubbs catalysts on the other hand are ruthenium II carbenoid complexes 5 Many variations of Grubbs catalysts are known Some have been modified with a chelating isopropoxybenzylidene ligand to form the related Hoveyda Grubbs catalyst nbsp Common Grubbs catalystsApplications editOlefin metathesis has several industrial applications Almost all commercial applications employ heterogeneous catalysts using catalysts developed well before the Nobel Prize winning work on homogeneous complexes 6 Representative processes include 1 The Phillips Triolefin and the Olefin conversion technology This process interconverts propylene with ethylene and 2 butenes Rhenium and molybdenum catalysts are used Nowadays only the reverse reaction i e the conversion of ethylene and 2 butene to propylene is industrially practiced however 6 Shell higher olefin process SHOP produces alpha olefins for conversion to detergents The process recycles certain olefin fractions using metathesis 7 Neohexene production which involves ethenolysis of isobutene dimers The catalyst is derived from tungsten trioxide supported on silica and MgO 1 5 Hexadiene and 1 9 decadiene useful crosslinking agents and synthetic intermediates are produced commercially by ethenolysis of 1 5 cyclooctadiene and cyclooctene The catalyst is derived from Re2O7 on alumina Synthesis of pharmaceutical drugs 8 Homogeneous catalyst potential edit Molecular catalysts have been explored for the preparation of a variety of potential applications 9 the manufacturing of high strength materials the preparation of cancer targeting nanoparticles 10 and the conversion of renewable plant based feedstocks into hair and skin care products 11 Types editSome important classes of olefin metathesis include Cross metathesis CM Ring opening metathesis ROM Ring closing metathesis RCM Ring opening metathesis polymerization ROMP Acyclic diene metathesis ADMET EthenolysisMechanism editHerisson and Chauvin first proposed the widely accepted mechanism of transition metal alkene metathesis 12 The direct 2 2 cycloaddition of two alkenes is formally symmetry forbidden and thus has a high activation energy The Chauvin mechanism involves the 2 2 cycloaddition of an alkene double bond to a transition metal alkylidene to form a metallacyclobutane intermediate The metallacyclobutane produced can then cycloeliminate to give either the original species or a new alkene and alkylidene Interaction with the d orbitals on the metal catalyst lowers the activation energy enough that the reaction can proceed rapidly at modest temperatures nbsp Olefin metathesis mechanismOlefin metathesis involves little change in enthalpy for unstrained alkenes Product distributions are determined instead by le Chatelier s Principle i e entropy nbsp Classification of Olefin metathesis reactionsCross metathesis and ring closing metathesis are driven by the entropically favored evolution of ethylene or propylene which can be removed from the system because they are gases Because of this CM and RCM reactions often use alpha olefins The reverse reaction of CM of two alpha olefins ethenolysis can be favored but requires high pressures of ethylene to increase ethylene concentration in solution The reverse reaction of RCM ring opening metathesis can likewise be favored by a large excess of an alpha olefin often styrene Ring opening metathesis usually involves a strained alkene often a norbornene and the release of ring strain drives the reaction Ring closing metathesis conversely usually involves the formation of a five or six membered ring which is enthalpically favorable although these reactions tend to also evolve ethylene as previously discussed RCM has been used to close larger macrocycles in which case the reaction may be kinetically controlled by running the reaction at high dilutions 13 The same substrates that undergo RCM can undergo acyclic diene metathesis with ADMET favored at high concentrations The Thorpe Ingold effect may also be exploited to improve both reaction rates and product selectivity Cross metathesis is synthetically equivalent to and has replaced a procedure of ozonolysis of an alkene to two ketone fragments followed by the reaction of one of them with a Wittig reagent Historical overview edit Olefin metathesis is a child of industry and as with many catalytic processes it was discovered by accident 1 As part of ongoing work in what would later become known as Ziegler Natta catalysis Karl Ziegler discovered the conversion of ethylene into 1 butene instead of a saturated long chain hydrocarbon see nickel effect 14 In 1960 a Du Pont research group polymerized norbornene to polynorbornene using lithium aluminum tetraheptyl and titanium tetrachloride 15 a patent by this company on this topic dates back to 1955 16 nbsp a reaction then classified as a so called coordination polymerization According to the then proposed reaction mechanism a RTiX titanium intermediate first coordinates to the double bond in a pi complex The second step then is a concerted SNi reaction breaking a CC bond and forming a new alkylidene titanium bond the process then repeats itself with a second monomer nbsp Only much later the polynorbornene was going to be produced through ring opening metathesis polymerisation The DuPont work was led by Herbert S Eleuterio Giulio Natta in 1964 also observed the formation of an unsaturated polymer when polymerizing cyclopentene with tungsten and molybdenum halides 17 In a third development leading up to olefin metathesis researchers at Phillips Petroleum Company in 1964 18 described olefin disproportionation with catalysts molybdenum hexacarbonyl tungsten hexacarbonyl and molybdenum oxide supported on alumina for example converting propylene to an equal mixture of ethylene and 2 butene for which they proposed a reaction mechanism involving a cyclobutane they called it a quasicyclobutane metal complex nbsp This particular mechanism is symmetry forbidden based on the Woodward Hoffmann rules first formulated two years earlier Cyclobutanes have also never been identified in metathesis reactions which is another reason why it was quickly abandoned Then in 1967 researchers led by Nissim Calderon at the Goodyear Tire and Rubber Company described a novel catalyst system for the metathesis of 2 pentene based on tungsten hexachloride ethanol and the organoaluminum compound EtAlMe2 The researchers proposed a name for this reaction type olefin metathesis 19 Formerly the reaction had been called olefin disproportionation nbsp In this reaction 2 pentene forms a rapid a matter of seconds chemical equilibrium with 2 butene and 3 hexene No double bond migrations are observed the reaction can be started with the butene and hexene as well and the reaction can be stopped by addition of methanol The Goodyear group demonstrated that the reaction of regular 2 butene with its all deuterated isotopologue yielded C4H4D4 with deuterium evenly distributed 20 In this way they were able to differentiate between a transalkylidenation mechanism and a transalkylation mechanism ruled out nbsp In 1971 Chauvin proposed a four membered metallacycle intermediate to explain the statistical distribution of products found in certain metathesis reactions 21 This mechanism is today considered the actual mechanism taking place in olefin metathesis nbsp Chauvin s experimental evidence was based on the reaction of cyclopentene and 2 pentene with the homogeneous catalyst tungsten VI oxytetrachloride and tetrabutyltin nbsp The three principal products C9 C10 and C11 are found in a 1 2 1 regardless of conversion The same ratio is found with the higher oligomers Chauvin also explained how the carbene forms in the first place by alpha hydride elimination from a carbon metal single bond For example propylene C3 forms in a reaction of 2 butene C4 with tungsten hexachloride and tetramethyltin C1 In the same year Pettit who synthesised cyclobutadiene a few years earlier independently came up with a competing mechanism 22 It consisted of a tetramethylene intermediate with sp3 hybridized carbon atoms linked to a central metal atom with multiple three center two electron bonds nbsp Experimental support offered by Pettit for this mechanism was based on an observed reaction inhibition by carbon monoxide in certain metathesis reactions of 4 nonene with a tungsten metal carbonyl 23 Robert H Grubbs got involved in metathesis in 1972 and also proposed a metallacycle intermediate but one with four carbon atoms in the ring 24 The group he worked in reacted 1 4 dilithiobutane with tungsten hexachloride in an attempt to directly produce a cyclomethylenemetallacycle producing an intermediate which yielded products identical with those produced by the intermediate in the olefin metathesis reaction This mechanism is pairwise nbsp In 1973 Grubbs found further evidence for this mechanism by isolating one such metallacycle not with tungsten but with platinum by reaction of the dilithiobutane with cis bis triphenylphosphine dichloroplatinum II 25 In 1975 Katz also arrived at a metallacyclobutane intermediate consistent with the one proposed by Chauvin 26 He reacted a mixture of cyclooctene 2 butene and 4 octene with a molybdenum catalyst and observed that the unsymmetrical C14 hydrocarbon reaction product is present right from the start at low conversion nbsp In any of the pairwise mechanisms with olefin pairing as rate determining step this compound a secondary reaction product of C12 with C6 would form well after formation of the two primary reaction products C12 and C16 In 1974 Casey was the first to implement carbenes into the metathesis reaction mechanism 27 nbsp Grubbs in 1976 provided evidence against his own updated pairwise mechanism nbsp with a 5 membered cycle in another round of isotope labeling studies in favor of the 4 membered cycle Chauvin mechanism 28 29 nbsp In this reaction the ethylene product distribution d 4 d 2 d 0 displaystyle d 4 d 2 d 0 nbsp at low conversion was found to be consistent with the carbene mechanism On the other hand Grubbs did not rule out the possibility of a tetramethylene intermediate The first practical metathesis system was introduced in 1978 by Tebbe based on the what later became known as the Tebbe reagent 30 In a model reaction isotopically labeled carbon atoms in isobutene and methylenecyclohexane switched places nbsp The Grubbs group then isolated the proposed metallacyclobutane intermediate in 1980 also with this reagent together with 3 methyl 1 butene 31 nbsp They isolated a similar compound in the total synthesis of capnellene in 1986 32 nbsp In that same year the Grubbs group proved that metathesis polymerization of norbornene by Tebbe s reagent is a living polymerization system 33 and a year later Grubbs and Schrock co published an article describing living polymerization with a tungsten carbene complex 34 While Schrock focussed his research on tungsten and molybdenum catalysts for olefin metathesis Grubbs started the development of catalysts based on ruthenium which proved to be less sensitive to oxygen and water and therefore more functional group tolerant Grubbs catalysts edit In the 1960s and 1970s various groups reported the ring opening polymerization of norbornene catalyzed by hydrated trichlorides of ruthenium and other late transition metals in polar protic solvents 35 36 37 This prompted Robert H Grubbs and coworkers to search for well defined functional group tolerant catalysts based on ruthenium The Grubbs group successfully polymerized the 7 oxo norbornene derivative using ruthenium trichloride osmium trichloride as well as tungsten alkylidenes 38 They identified a Ru II carbene as an effective metal center and in 1992 published the first well defined ruthenium based olefin metathesis catalyst PPh3 2Cl2Ru CHCH CPh2 39 nbsp The corresponding tricyclohexylphosphine complex PCy3 2Cl2Ru CHCH CPh2 was also shown to be active 40 This work culminated in the now commercially available 1st generation Grubbs catalyst 41 42 Schrock catalysts edit Schrock entered the olefin metathesis field in 1979 as an extension of work on tantalum alkylidenes 43 The initial result was disappointing as reaction of CpTa CH t Bu Cl2 with ethylene yielded only a metallacyclopentane not metathesis products 44 nbsp But by tweaking this structure to a PR3Ta CHt bu Ot bu 2Cl replacing chloride by t butoxide and a cyclopentadienyl by an organophosphine metathesis was established with cis 2 pentene 45 In another development certain tungsten oxo complexes of the type W O CHt Bu Cl 2 PEt 3 were also found to be effective 46 Schrock alkylidenes for olefin metathesis of the type Mo NAr CHC CH3 2R OC CH3 CF3 2 2 were commercialized starting in 1990 47 48 nbsp The first asymmetric catalyst followed in 1993 49 nbsp With a Schrock catalyst modified with a BINOL ligand in a norbornadiene ROMP leading to highly stereoregular cis isotactic polymer See also editAlkane metathesis Alkyne metathesis Enyne metathesis Salt metathesis reactionReferences edit a b c Lionel Delaude Alfred F Noels 2005 Metathesis Kirk Othmer Encyclopedia of Chemical Technology Weinheim Wiley VCH doi 10 1002 0471238961 metanoel a01 ISBN 978 0 471 23896 6 Astruc D 2005 The metathesis reactions from a historical perspective to recent developments New Journal of Chemistry 29 1 42 56 doi 10 1039 b412198h S2CID 98046245 The Nobel Prize in Chemistry 2005 Press release Nobelprize org 5 October 2005 R R Schrock 1986 High oxidation state molybdenum and tungsten alkylidene complexes Accounts of Chemical Research 19 11 342 348 doi 10 1021 ar00131a003 Ileana Dragutan Valerian Dragutan Petru Filip 2005 Recent developments in design and synthesis of well defined ruthenium metathesis catalysts a highly successful opening for intricate organic synthesis Arkivoc 105 129 Archived from the original on 12 May 2006 Retrieved 6 October 2005 a b Ghashghaee Mohammad 2018 Heterogeneous catalysts for gas phase conversion of ethylene to higher olefins Reviews in Chemical Engineering 34 5 595 655 doi 10 1515 revce 2017 0003 S2CID 103664623 Klaus Weissermel Hans Jurgen Arpe 1997 Industrial Organic Chemistry 3rd ed John Wiley amp Sons ISBN 3 527 28838 4 McCauley JA McIntyre CJ Rudd MT Nguyen KT Romano JJ Butcher JW Gilbert KF Bush KJ Holloway MK Swestock J Wan BL Carroll SS DiMuzio JM Graham DJ Ludmerer SW Mao SS Stahlhut MW Fandozzi CM Trainor N Olsen DB Vacca JP Liverton NJ March 2010 Discovery of vaniprevir MK 7009 a macrocyclic hepatitis C virus NS3 4a protease inhibitor Journal of Medicinal Chemistry 53 6 2443 63 doi 10 1021 jm9015526 PMID 20163176 Kotha S Waghule GT June 2012 Diversity Oriented Approach to Crownophanes by Enyne Metathesis and Diels Alder Reaction as Key Steps The Journal of Organic Chemistry 77 14 6314 6318 doi 10 1021 jo300766f PMID 22731677 Matson JB Grubbs RH 2008 Synthesis of Fluorine 18 Functionalized Nanoparticles for use as in vivo Molecular Imaging Agents PDF Journal of the American Chemical Society 130 21 6731 6733 doi 10 1021 ja802010d PMID 18452296 Dow Corning and Elevance Announce Partnership to Market Naturally Derived Ingredients in Personal Care Applications Press release Elevance Renewable Sciences 9 September 2008 Archived from the original on 9 December 2011 Retrieved 19 January 2012 Jean Louis Herisson Par Chauvin Yves 1971 Catalyse de transformation des olefines par les complexes du tungstene II Telomerisation des olefines cycliques en presence d olefines acycliques Die Makromolekulare Chemie in French 141 1 161 176 doi 10 1002 macp 1971 021410112 Sambasivarao Kotha Kuldeep Singh 2007 Cross enyne and ring closing metathesis cascade A building block approach suitable for diversity oriented synthesis of densely functionalized macroheterocycles with amino acid scaffolds European Journal of Organic Chemistry 2007 35 5909 5916 doi 10 1002 ejoc 200700744 Ziegler Karl Holzkamp E Breil H Martin H 1955 Polymerisation von Athylen und anderen Olefinen Angewandte Chemie 67 16 426 Bibcode 1955AngCh 67 426Z doi 10 1002 ange 19550671610 Truett W L Johnson D R Robinson I M Montague B A 1960 Polynorbornene by Coordination Polymerization Journal of the American Chemical Society 82 9 2337 2340 doi 10 1021 ja01494a057 A W Anderson and N G Merckling U S U S Patent 2 721 189 18 October 1955 Natta G Dall asta G Mazzanti G 1964 Stereospecific Homopolymerization of Cyclopentene Angewandte Chemie International Edition in English 3 11 723 729 doi 10 1002 anie 196407231 Banks R L Bailey G C 1964 Olefin Disproportionation A New Catalytic Process Industrial amp Engineering Chemistry Product Research and Development 3 3 170 173 doi 10 1021 i360011a002 Calderon N Chen Hung Yu Scott Kenneth W 1967 Olefin metathesis A novel reaction for skeletal transformations of unsaturated hydrocarbons Tetrahedron Letters 8 34 3327 3329 doi 10 1016 S0040 4039 01 89881 6 Calderon Nissim Ofstead Eilert A Ward John P Judy W Allen Scott Kenneth W 1968 Olefin metathesis I Acyclic vinylenic hydrocarbons Journal of the American Chemical Society 90 15 4133 4140 doi 10 1021 ja01017a039 Jean Louis Herisson Par Chauvin Yves 1971 Catalyse de transformation des olefines par les complexes du tungstene II Telomerisation des olefines cycliques en presence d olefines acycliques Die Makromolekulare Chemie 141 1 161 176 doi 10 1002 macp 1971 021410112 S Lewandos G Pettit R 1971 A proposed mechanism for the metal catalysed disproportionation reaction of olefins Tetrahedron Letters 12 11 789 793 doi 10 1016 S0040 4039 01 96558 X Lewandos Glenn S Pettit R 1971 Mechanism of the metal catalyzed disproportionation of olefins Journal of the American Chemical Society 93 25 7087 7088 doi 10 1021 ja00754a067 Grubbs Robert H Brunck Terence K 1972 Possible intermediate in the tungsten catalyzed olefin metathesis reaction Journal of the American Chemical Society 94 7 2538 2540 doi 10 1021 ja00762a073 Biefeld Carol G Eick Harry A Grubbs Robert H 1973 Crystal structure of bis triphenylphosphine tetramethyleneplatinum II Inorganic Chemistry 12 9 2166 2170 doi 10 1021 ic50127a046 Katz Thomas J McGinnis James 1975 Mechanism of the olefin metathesis reaction Journal of the American Chemical Society 97 6 1592 1594 doi 10 1021 ja00839a063 Casey Charles P Burkhardt Terry J 1974 Reactions of diphenylcarbene pentacarbonyltungsten 0 with alkenes Role of metal carbene complexes in cyclopropanation and olefin metathesis reactions Journal of the American Chemical Society 96 25 7808 7809 doi 10 1021 ja00832a032 Grubbs Robert H Burk Patrick L Carr Dale D 1975 Mechanism of the olefin metathesis reaction Journal of the American Chemical Society 97 11 3265 3267 doi 10 1021 ja00844a082 Grubbs Robert H Carr D D Hoppin C Burk P L 1976 Consideration of the mechanism of the metal catalyzed olefin metathesis reaction Journal of the American Chemical Society 98 12 3478 3483 doi 10 1021 ja00428a015 Tebbe F N Parshall G W Reddy G S 1978 Olefin homologation with titanium methylene compounds Journal of the American Chemical Society 100 11 3611 3613 doi 10 1021 ja00479a061 Howard T R Lee J B Grubbs R H 1980 Titanium metallacarbene metallacyclobutane reactions stepwise metathesis Journal of the American Chemical Society 102 22 6876 6878 doi 10 1021 ja00542a050 Stille John R Grubbs Robert H 1986 Synthesis of DELTA 9 12 capnellene using titanium reagents Journal of the American Chemical Society 108 4 855 856 doi 10 1021 ja00264a058 Gilliom Laura R Grubbs Robert H 1986 Titanacyclobutanes derived from strained cyclic olefins the living polymerization of norbornene Journal of the American Chemical Society 108 4 733 742 doi 10 1021 ja00264a027 Schrock R R Feldman J Cannizzo L F Grubbs R H 1987 Ring opening polymerization of norbornene by a living tungsten alkylidene complex Macromolecules 20 5 1169 1172 Bibcode 1987MaMol 20 1169S doi 10 1021 ma00171a053 Michelotti Francis W Keaveney William P 1965 Coordinated Polymerization of the Bicyclo 2 2 1 heptene 2 Ring System Norbornene in Polar Media Journal of Polymer Science Part A General Papers 3 3 895 905 doi 10 1002 pol 1965 100030305 Rinehart Robert E Smith Homer P 1965 The Emulsion Polymerization of the Norbornene Ring System Catalyzed by Noble Metal Compounds Journal of Polymer Science Part B Polymer Letters 3 12 1049 1052 Bibcode 1965JPoSL 3 1049R doi 10 1002 pol 1965 110031215 Porri Lido Rossi Renzo Diversi Pietro Lucherini Antonio 1974 Ring Opening Polymerization of Cycloolefins with Catalysts Derived from Ruthenium and Iridium Die Makromolekulare Chemie 175 11 3097 3115 doi 10 1002 macp 1974 021751106 Novak Bruce M Grubbs Robert H 1988 The ring opening metathesis polymerization of 7 oxabicyclo 2 2 1 hept 5 ene derivatives a new acyclic polymeric ionophore Journal of the American Chemical Society 110 3 960 961 doi 10 1021 ja00211a043 Nguyen Sonbinh T Johnson Lynda K Grubbs Robert H Ziller Joseph W 1992 Ring opening metathesis polymerization ROMP of norbornene by a Group VIII carbene complex in protic media PDF Journal of the American Chemical Society 114 10 3974 3975 doi 10 1021 ja00036a053 Nguyen Sonbinh T Grubbs Robert H Ziller Joseph W 1993 Syntheses and activities of new single component ruthenium based olefin metathesis catalysts Journal of the American Chemical Society 115 21 9858 9859 doi 10 1021 ja00074a086 Schwab Peter France Marcia B Ziller Joseph W Grubbs Robert H 1995 A Series of Well Defined Metathesis Catalysts Synthesis of RuCl2 CHR PR3 2 and Its Reactions Angewandte Chemie International Edition in English 34 18 2039 2041 doi 10 1002 anie 199520391 Schwab Peter Grubbs Robert H Ziller Joseph W 1996 Synthesis and Applications of RuCl2 CHR PR3 2 The Influence of the Alkylidene Moiety on Metathesis Activity Journal of the American Chemical Society 118 100 110 doi 10 1021 ja952676d Schrock R R Meakin P 1974 Pentamethyl complexes of niobium and tantalum Journal of the American Chemical Society 96 16 5288 5290 doi 10 1021 ja00823a064 McLain S J Wood C D Schrock R R 1979 Preparation and characterization of tantalum III olefin complexes and tantalum V metallacyclopentane complexes made from acyclic a olefins Journal of the American Chemical Society 101 16 4558 4570 doi 10 1021 ja00510a022 Schrock R Rocklage Scott Wengrovius Jeffrey Rupprecht Gregory Fellmann Jere 1980 Preparation and characterization of active niobium tantalum and tungsten metathesis catalysts Journal of Molecular Catalysis 8 1 3 73 83 doi 10 1016 0304 5102 80 87006 4 Wengrovius Jeffrey H Schrock Richard R Churchill Melvyn Rowen Missert Joseph R Youngs Wiley J 1980 Multiple metal carbon bonds 16 Tungsten oxo alkylidene complexes as olefins metathesis catalysts and the crystal structure of W O CHCMe3 PEt3 Cl2 Journal of the American Chemical Society 102 13 4515 4CF6 doi 10 1021 ja00533a035 Schrock Richard R Murdzek John S Bazan Gui C Robbins Jennifer Dimare Marcello O Regan Marie 1990 Synthesis of molybdenum imido alkylidene complexes and some reactions involving acyclic olefins Journal of the American Chemical Society 112 10 3875 3886 doi 10 1021 ja00166a023 Bazan Guillermo C Oskam John H Cho Hyun Nam Park Lee Y Schrock Richard R 1991 Living Ring Opening Metathesis Polymerization of 2 3 Difunctionalized 7 Oxanorbornenes and 7 Oxanorbornadienes by Mo CHCMe2R N 2 6 C6H3 i Pr2 O t Bu 2 and Mo CHCMe2R N 2 6 C6H3 i Pr2 OCMe2CF3 2 113 18 6899 6907 doi 10 1021 ja00018a028 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help McConville David H Wolf Jennifer R Schrock Richard R 1993 Synthesis of chiral molybdenum ROMP initiators and all cis highly tactic poly 2 3 R 2norbornadiene R CF3 or CO2Me Journal of the American Chemical Society 115 10 4413 4414 doi 10 1021 ja00063a090 Further reading edit Olefin Metathesis Big Deal Reaction 80 51 2002 29 33 doi 10 1021 cen v080n016 p029 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Olefin Metathesis The Early Days 80 51 2002 34 38 doi 10 1021 cen v080n029 p034 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Schrock R R 1990 Living ring opening metathesis polymerization catalyzed by well characterized transition metal alkylidene complexes Accounts of Chemical Research 23 5 158 165 doi 10 1021 ar00173a007 Schrock R R Hoveyda A H 2003 Molybdenum and Tungsten Imido Alkylidene Complexes as Efficient Olefin Metathesis Catalysts Angewandte Chemie International Edition 42 38 4592 4633 doi 10 1002 anie 200300576 PMID 14533149 S2CID 35370749 Samojlowicz C Grela K 2009 Ruthenium Based Olefin Metathesis Catalysts Bearing N Heterocyclic Carbene Ligands Chemical Reviews 109 8 3708 3742 doi 10 1021 cr800524f PMID 19534492 Vougioukalakis G C Grubbs R H 2010 Ruthenium Based Heterocyclic Carbene Coordinated Olefin Metathesis Catalysts Chemical Reviews 110 3 1746 1787 doi 10 1021 cr9002424 PMID 20000700 S2CID 4589661 Trnka T M Grubbs R H 2001 The Development of L2X2Ru CHR Olefin Metathesis Catalysts An Organometallic Success Story Accounts of Chemical Research 34 1 18 29 doi 10 1021 ar000114f PMID 11170353 S2CID 22145255 Grubbs R H Chang S 1998 Recent advances in olefin metathesis and its application in organic synthesis Tetrahedron 54 18 4413 4450 doi 10 1016 S0040 4020 97 10427 6 Grubbs R H 2004 Olefin metathesis Tetrahedron 60 34 7117 7140 doi 10 1016 j tet 2004 05 124 Grela K 2010 Grela K ed Progress in metathesis chemistry Editorial for Open Access Thematic Series Beilstein Journal of Organic Chemistry 6 1089 1090 doi 10 3762 bjoc 6 124 PMC 3002079 PMID 21160917 Retrieved from https en wikipedia org w index php title Olefin metathesis amp oldid 1181945322, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.