36216-84-9

Upstream product

• 56054-39-8 Mo(η6-PhPMe2)(PMe2Ph)3 
• 36151-25-4 [WCl₄(P(C₆H₅)3)2] 
• 30411-60-0 WCl₄(PMe₂Ph)2 
• 39049-86-0 WCl₂(P(CH₃)2C₆H₅)4 
• 7732-18-5 water 
• 672-66-2 Dimethyl(phenyl)phosphine 

Downstream Products

• 111717-78-3 WO(S₂C(P(CH₃)2(C₆H₅))OC₃H₇)(S₂COC₃H₇) 
• 111819-56-8 WO(S₂C(P(C₆H₅)(CH₃)2)OC₃H₇)(S₂COC₃H₇) 

Relevant academic research and scientific papers

Two isomers of WCl3(PMe2Ph)3 and their potential for equilibration with W2Cl6(PMe2Ph)n

A new (comproportionation) synthesis of WCl3(PMe2Ph)3, as well as the coexistence of two structural isomers, is reported. These are characterized by 1H NMR spectroscopy and single-crystal X-ray diffraction. Equilibration of these two species is effected at 80°C, with mer converting completely to fac. It is not possible to convert the WCl3L3 (L = PMe2Ph) species to either of the known dimers W2Cl6Ln, (n = 3, 4). The mer → fac isomerization is shown to be catalyzed by WCl4L2 (but not by WCl2L4). The mechanism of the comproportionation synthesis of WCl3L3 strongly favors the mer isomer, and a mechanism is proposed to account for this. Photolysis of a mixture of [WCl3(PMe2Ph)2]2 in the presence of excess PMe2Ph completely converts the dimer to mer-WCl3(PMe2Ph)3. Mechanistic features which cause the stereoselectivity of this reaction are discussed. Cell parameters for fac-WCl3L3 (-165°C): a = 9.476(2) A?, b = 18.091 (5) A?, c = 9.185(2) A?, α = 98.62(1)°, β = 101.53(1)°, γ = 93.49(1)° with Z = 2 in space group P1. Cell parameters for mer WCl3L3 at -155°C, a = 16.031(3) A?, b = 10.297(1) A?, c = 17.913(3), β = 113.86(1)°, Z = 4, and space group P21/c.

Origin of the Two Significantly Different W-Cl Bond Lengths for Chemically Equivalent Bonds in mer-

The observation of two significantly different W-Cl bond lengths for chemically equivalent bonds, previously reported for mer-, has been reinterpreted as an artifact due to cocrystallization with an isostructural oxo impurity, cis-mer-WOCl

Complexes containing unbridged homonuclear or heteronuclear quadruple bonds. Crystal and molecular structures of MoWCl4(PMePh2)4, MoWCl4(PMe3)4, and Cl2(PMe3)2MoWCl2(PMePh 2)2

The reactions of Mo(η6-PhPMePh)(PMePh2)3 and Mo(η6-PhPMe2)(PMe2Ph)3 with MoCl4(THF)2 yield the homonuclear unbridged quadruply bonded complexes Mo2Cl4(PR3)4 (PR3 = PMePh2 (1), PMe2Ph (2)). Complex 1 readily undergoes phosphine substitution with PMe3 to yield Mo2Cl4(PMe3)4 (3). The reactions of Mo(η6-PhPMe2)(PMe2Ph)3 and Mo(η6-PhPMePh)(PMePh2)3 with WCl4(PPh3)2 yield the complexes MoWCl4(PR3)4 (PR3 = PMe2Ph (4), PMePh2 (5)), which are among the first to contain an unbridged quadruple bond between two different elements. Complex 5 undergoes phosphine substitution reactions with PMe3 to give sequentially Cl2(PMe3)2MoWCl2(PMePh 2)2 (6) and then MoWCl4(PMe3)4 (7). Complex 4 can also be synthesized by reacting 5 with PMe2Ph. The 31P and 1H NMR spectra, electronic and visible spectra, and cyclic voltammograms of these complexes are interpreted, and the crystal and molecular structures of 5-7 are reported. Compounds 5 and 7 were found to have disordered arrangements of the metal atoms; compound 6 with the different phosphine ligands on the metal atoms is, however, ordered with a Mo4-W bond length of 2.207 (1) A?. In 6 and 7 the molecules have crystallographic 2-fold symmetry. In all three structures the ligand arrangement over the metal-metal bond defines an eclipsed geometry with chlorine next to phosphine across the bond in a pseudo-D2d arrangement. The metal-metal distances in 5 and 7 are 2.208 (4) (average) and 2.2092 (7) A?, respectively. These values are close to distances expected on the basis of homonuclear M4-M bonds, and therefore there is no extra shortening of these bonds due to electronegativity differences. Crystal data: 5, monoclinic, space group P21/a, a = 21.511 (4) A?, b = 12.176 (6) A?, c = 40.863 (8) A?, β = 92.65(2)°, V = 10692 A?3, Dcalcd = 1.52 g cm-3 for Z = 8, R = 0.0957 for 3554 observed (I > 3σ(I)) reflections; 6, monoclinic, space group I2/a, a = 16.817 (4) A?, b = 11.925 (3) A?, c = 19.685 (5) A?, β = 103.87 (2)°, V = 3832.4 A?3, Dcalcd = 1.69 g cm-3 for Z = 4, R = 0.0364 for 2203 observed reflections; 7, monoclinic, space group I2/a, a = 17.312 (4) A?, b = 9.193 (1) A?, c = 19.085 (3) A?, β = 119.69 (2)°, V = 2638.9 A?3, Dcalcd = 1.57 g cm-3 for Z = 4, R = 0.0312 for 2084 observed reflections.