36216-85-0

Upstream product

• 630-19-3 pivalaldehyde 
• 21889-88-3 hept-6-en-2-one 
• 3664-60-6 7-octene-2-one 
• 6388-72-3 2-(4-methoxyphenyl)oxirane 
• 90245-62-8 WCl₂(PMePh₂)4 
• 75-21-8 oxirane 
• 75-56-9 methyloxirane 
• 21490-63-1 2,3-trans-epoxybutane 
• 558-30-5 2-methyl-1,2-epoxypropane 
• 75598-29-7 W^IVCl₄(PMePh₂)2 
• 7732-18-5 water 
• 1486-28-8 diphenyl(methyl)phosphine 
• 102342-13-2 W(O)Cl₂(P(CH₃)(C₆H₅)2)2(CO) 
• 67-68-5 dimethyl sulfoxide 

Downstream Products

• 133523-04-3 W(O)Cl₂(P(CH₃)(C₆H₅)2)((C₆H₅)2P(O)CH₂CHCH₂) 
• 133548-73-9 W(O)Cl₂(P(CH₃)(C₆H₅)2)((C₆H₅)2P(CH₂)2P(C₆H₅)2) 
• 102342-14-3 W(O)Cl₂(PMePh₂)2(t-butylisonitrile) 
• 102307-88-0 W(O)Cl2(PMePh2)2(η2-butadiene) 
• 123995-87-9 W(O)Cl₂(PMePh₂)2(allyl alcohol) 
• 124072-09-9 W(O)Cl₂(PMePh₂)2(phenyl acetylene) 
• 102307-86-8 W(O)Cl₂(PMePh₂)2(ethylene) 
• 102342-13-2 W(O)Cl₂(P(CH₃)(C₆H₅)2)2(CO) 
• 36151-19-6 trans-[WCl₄(PMePh₂)2] 
• 102307-87-9 W(O)Cl₂(PMePh₂)2(propylene) 

Relevant academic research and scientific papers

On the mechanism of oxygen atom or nitrene group transfer in reactions of epoxides and aziridines with tungsten(II) compounds

The tungsten(II) complexes WCl2(PMePh2)4 (1) and WCl2(CH2=CH2)2(PMePh 2)2 (2) react with epoxides and aziridines to form tungsten(IV)-oxo and -imido complexes. The relative reactivities of epoxides with 2 have been determined from competition experiments. More substituted epoxides are harder to deoxygenate: the reactivities of ethylene, isobutylene, and tetramethylethylene oxides fall in the geometric progression 100:10:1. cis-2-Butene oxide is deoxygenated faster than its trans isomer. Reaction occurs with predominant (≥85%) retention of configuration (e.g. cis epoxides to cis olefins). The reaction of 2 with ethylene-d4 oxide yields W(O)Cl2(CH2=CH2)(PMePh2)2 (4) and uncoordinated CD2=CD2. The data suggest that de-epoxidation occurs via oxygen atom abstraction, and not via an oxametallacyclobutane which rearranges to an oxo-ethylene complex. Similarly, the tungsten center is suggested to attack the nitrogen atom of the aziridines, rather than react by initial oxidative addition of a C-N bond. This is indicated by the observation of an N-bound complex of aziridine and by the much slower rates of reaction for aziridines with bulky substituents on the nitrogen. The reactivities of para-substituted styrene epoxides are not strongly affected by the nature of the substituent (a ρ+ value of -0.5 is calculated with Hammett σ+ parameters) indicating that the transition state is not very polar, although there appears to be some conjugation between the phenyl ring and the epoxide. In sum, the data are most consistent with either concerted oxygen or nitrene transfer to tungsten or a mechanism involving a short-lived radical intermediate.

A tungsten-mediated closed cycle of reactivity for the reduction of CO 2 to CO

The recycling of CO2 by reduction to CO is an important objective in the context of renewable carbon feedstock chemicals. A tungsten-mediated reduction of CO2 to CO reported by Mayer and coworkers has been re-examined, and it is shown that a series of four well-defined stoichiometric steps can be executed which form a closed cycle and sum as CO2 + 2H+ + 2e- → CO + H 2O. Energetic parameters of this system are probed by cyclic voltammetry, by calculations of gas-phase reaction enthalpies for each of the four steps, and by calculation of the WO bond dissociation energy for the tungsten species that results from oxidation addition of CO2.

Reactions of ML4Cl2 (M = Mo, W; L = PMe3, PMePh2) with epoxides, episulfides, CO2, heterocumulenes, and other substrates: A comparative study of oxidative addition by oxygen atom, sulfur atom, or nitrene group transfer

A comparative survey of the reactivity of the divalent molybdenum and tungsten chloro-phosphine complexes ML4Cl2 (M = Mo, W; L = PMe3, PMePh2) toward oxidation by a variety of oxygen atom, sulfur atom, and nitrene donors is presented. In general, reactions result in net two-electron oxidation of the metal center, producing metal oxo, sulfido, and imido complexes. The reactions can also be described as oxidative addition reactions, in many cases oxidative addition of C=X double bonds. Reactions are apparently thermodynamically driven by the propensity of Mo and W to form strong multiple bonds with oxygen, sulfur, and nitrogen. ML4Cl2 compounds react with ethylene oxide and ethylene sulfide to produce oxo and sulfido tris(phosphine) species, M(E)L3Cl2 (E = O, S), in equilibrium with oxo and sulfido ethylene species M(E)(CH2=CH2)L2Cl2. Isocyanates (RN=C=O; R = tBu, p-tolyl) and tBuN=C=NtBu react to form imido tris(phosphine) and imido carbonyl or imido isonitrile complexes, respectively. Phosphine sulfides are desulfurized forming sulfido complexes, but phosphine oxides are unreactive. The π-acids formed in these reactions - for instance, CO from cleavage of RNCO - bind more strongly to the tungsten(IV) versus the molybdenum(IV) oxo, sulfido, and imido products. Similarly, the equilibria for π-acid coordination are more favorable when the ligand is PMePh2 than when L = PMe3. For all of the complexes, reactions are slowed by free phosphine, consistent with a mechanism involving an initial dissociation of a phosphine ligand followed by trapping of the coordinatively unsaturated species by the oxidizing substrate. Ligand loss from ML4Cl2 is rapid for L = PMePh2 at ambient temperatures but slower for L = PMe3, with half-lives for PMe3 loss of 18 min at 24°C for Mo(PMe3)4Cl2 and 6 min at 69°C for W(PMe3)4Cl2. For the molybdenum complexes MoL4Cl2 (L = PMe3, PMePh2), dimerization to the known Mo(II) quadruply bound species Mo2L4Cl4 is competitive with oxidation at the metal center. In reactions involving stronger oxidants (SO2, DMSO, and N2O), the formation of trivalent species ML3Cl3 is often observed, indicating that chlorine atom transfer processes also occur.

Oxygen and chlorine atom transfer between tungsten, molybdenum, and rhenium complexes. Competition between one- and two-electron pathways

Inter-metal oxygen atom transfer reactions between molybdenum, tungsten, and rhenium complexes are described. With only chloride and PMePh2 as supporting ligands, oxygen atom transfer is observed from rhenium to molybdenum and tungsten and from

Deoxygenative coupling of ketones and alkenes by tungsten(II) compounds

Tungsten(II) compounds such as WCl2(PMePh2)4 (1) react with acetone and ethylene to give a good yield of the tungsten(IV)-oxo complexes W(O)(CH2=CH2)Cl2(PMePh2)2 (4) and a moderate amount of 3-methyl-1-butene. Cyclopentanone and ethylene plus 1 yield 4 and vinylcyclopentane; methyl vinyl ketone and ethylene give 4 and 3-methyl-1,4-pentadiene. The reaction of cyclopentanone and propylene with 1 yields a small amount of 2-cyclopentylpropene. Intramolecular deoxygenative coupling occurs with 6- and 7-en-2-ones to form 1-methyl-2-methylene-substituted cyclopentyl and cyclohexyl ring systems, respectively. The net result of these reactions is transfer of the ketone oxygen atom to tungsten, accompanied with its replacement by a hydrogen and a vinyl group. The suggested mechanism for this deoxygenative coupling (Scheme I) is coordination of both the ketone and ethylene to tungsten, coupling to form a 2-oxametallacyclopentane, β-hydrogen elimination to an allyloxy hydride species, C-O bond cleavage to an oxo allyl hydride complex, and reductive elimination of alkene. Consistent with the suggestion of an oxametallacycle, hydrolysis of the reaction mixture of 1 and 6-hepten-2-one provides stereospecifically trans-1,2-dimethylcyclopentanol. The enones methyl vinyl ketone and 5-hexen-2-one react with 1 to form stable complexes in which the enone is bound in an η4 fashion, similar to the proposed mixed alkene ketone intermediates in the coupling reactions. A related tungsten(II) butadiene complex, WCl2(CH2= CHCH=CH2) (PMePh2)2, has also been isolated.

Oxidative addition of carbon-oxygen and carbon-nitrogen double bonds to WCl2(PMePh2)4. Synthesis of tungsten metallaoxirane and tungsten oxo- and imido-alkylidene complexes

WCl2L4 (1, L = PMePh2) reacts rapidly with a variety of ketones and aldehydes to form bis(η2-ketone) or bis(η2-aldehyde) complexes WCl2(η2-O=CRR′)2L2 (2, 3)