54005-29-7

Upstream product

• 1486-28-8 diphenyl(methyl)phosphine 
• 29484-75-1 PdCl2(PMePh2)2 
• 7647-15-6 sodium bromide 
• 24981-80-4 tetrakis(methyldiphenylphosphine)palladium 
• 39248-62-9 diphenylbismuthanyl bromide 
• 588-73-8 (Z)-β-bromostyrene 
• 588-72-7 [(E)-2-bromoethenyl]benzene 
• 1233923-53-9 trans-[Pd(CHCHC₆H₄NO₂)Br(diphenylmethylphosphine)2] 
• 1233923-52-8 trans-[Pd(CHCHC₆H₄CF₃)Br(diphenylmethylphosphine)2] 

Downstream Products

• 25044-96-6 bis(triphenylphosphine)palladium dibromide 
• 68487-95-6 [(CH₃)(C₆H₅)2P]3PdBr⁽¹⁺⁾ 
• 122109-21-1 trans-(MePh₂P)2palladium(II)BrI 
• 122109-23-3 trans-(MePh₂P)2palladium(II)Br(N₃) 

Relevant academic research and scientific papers

Substituent effects on P-C reductive elimination from styrylpalladium(II) phosphine complexes

A series of styrylpalladium phosphine complexes, trans-[Pd(CH=CHAr) Br(PMeAr′2)2] (1: Ar = Ph, 4-MeOC6H 4, 4-MeC6H4, 4-F3CC 6H4, 4-O2NC6H4; Ar′ = Ph, 4-MeC6H4, 4-FC6H4), have been prepared, and their P-C reductive elimination in the presence of added PMeAr′2 (1-4 equiv) in CD2Cl2 has been examined by kinetic experiments. All complexes are converted to [Pd(η2-ArCH=CHPMeAr′2)(PMeAr′2) 2]Br (3) at 40 °C in high selectivity. The kinetic data are consistent with the reaction process involving prior association of 1 with PMeAr′2 to form a five-coordinate intermediate, trans-[Pd(CH=CHAr)Br(PMeAr′2)3] (A), which subsequently undergoes P-C reductive elimination to give 3. The pseudo-first-order rate constant (kobsd) increases as the amount of added PMeAr′2 ([PMeAr′2]) increases, according to the equation 1/kobsd = 1/kK[PMeAr′2] + 1/k, where K = [A]/[1][PMeAr′2] and k stands for the rate constant for the conversion of A to 3. The association constant K and the rate constant k exhibit a good Hammett correlation with the σp values of para substituents on the Ar and Ar′ groups, respectively: log(K Y/KH) = [+0.84(3)]σp + 0.02(1) (for Ar groups); log(KY/KH) = [+4.2(4)]Σp + 0.09(7) (for Ar′ groups); log(kY/kH) = [-2.43(9)]σp + 0.01(3) (for Ar groups); [-4.8(4)] Σp-0.11(8) (for Ar′ groups). Thus, the K value increases as the electron-withdrawing ability of para substituents increases, while the k value increases as the electron-donating ability of para substituents increases. The P-C reductive elimination mechanism from A to 3 is discussed.

Mechanism of C-P reductive elimination from trans-[Pd(CH=CHPh)Br(PMePh2)2]

The (E)- and (Z)-styryl isomers of trans-[Pd(CH=CHPh)Br(PMePh 2)2](1a) and [Pd(n2-PhCH= CHPMePh2) Br(PMePh2)] (2a) were prepared, and their C-P reductive elimination (1a - 2a) and C-P oxidative addition (2a - 1a

Reaction of trans-Pd(styryl)Br(PMePh2)2 with styryl bromide affording 1,4-diphenyIbutadiene. An unexpected homocoupling process induced by P-C reductive elimination

Reaction of (Z)-styryl bromide (1) with PhB(OH)2 in toluene at 80 °C for 1 h in the presence of Pd(PPh3)4 (1.5 mol %) and an aqueous solution of K2CO3 (3 equiv) affords (Z)-stilbene as the cross-coupling product in 99% yield. On the other hand, the same reaction of the (E)-isomer of 1 forms considerable amounts of homocoupling products (1,4-diphenylbutadiene (2, 22%) and biphenyl (27%)) in addition to the cross-coupling product ((E)-stilbene, 73%). The formation of 2 was examined by kinetic experiments using trans-Pd(CH=CHPh)Br(PMePh2)2 (3) as a model of the presumed intermediate. Complex 3 reacts with 1 at 50 °C for 5 h, giving 2 (91%) and irans-PdBr2(PMePh2) 2 (4, 92%), together with a small amount of Pd(η2- PhCH=CHPMePh2)Br(PMePh2) (5, 8%). The reaction rate shows firstorder dependence on the concentration of 3 and 5, respectively, but is independent of the concentration of 1. A novel homocoupling process induced by P-C reductive elimination from 3 giving 5 is proposed.

Different ways to distort a tetracapped tetrahedron on route to forming an E4M4 cubane: The case of [E4(Pd(PPh2Me)2)4] [Ph2EX2]2 (E = Sb, X = Cl; E = Bi, X = Br)

Tetrakis(diphenylmethylphosphine)palladium reacts with diphenylantimony chloride or diphenyl-bismuth bromide to give [E4(PdL2)4][Ph2EX2] 2 (L = PPh2Me, 1: E = Sb, X = Cl; 2: E = Bi, X = Br) which have been characterized spectroscopically and by single-crystal X-ray diffraction for [Sb4(PdL2)4] [Ph2SbCl2]2· 0.5THF and [Bi4(PdL2)4] [Ph2BiBr2]2. These compounds are electron-rich based on electron counting formalisms. The additional cluster electrons can be rationalized by the ability of group 15 elements to show hypervalency, particularly those elements such as Sb and Bi which show more metal character. The electronic structure of the compounds and of related species has been examined by EHT and DFT calculations. Relationships to other cubane-derived structures are derived, and the stability of structurally related M4E4 hypothetical clusters is discussed. Compounds 1 and 2 decompose thermally to give Bi2Pd and SbPd.

Solid-state distortions of nominally square-planar palladium and platinum (R3P)2MX2 complexes as determined by a combination of 13C{1H} and 31P{1H} NMR spectroscopy

Phosphorus-31 and carbon-13 NMR spectra have been obtained for a series of 20 (R3P)2MX2 complexes (R3P = MePh2P and Me2PhP; M = Pd, Pt; X = Cl, Br, I, CN, N3) in the solid state by cross-polarization and magic-angle-spinning (CP/MAS) techniques. Comparison of these data with spectral data obtained at 300 K in CDCl3 solutions was made in order to investigate the influence of local symmetry on 31P and 13C chemical shifts in the solid state. It was found that most of these compounds, which have regular square-planar geometries in solution, are distorted in the solid state. The solid-state distortions are evidenced by additional 31P and 13C resonances in the CP/MAS spectra as compared to the solution spectra. The nature and degree of these distortions are discussed.