734-60-1

Upstream product

• 1005-33-0 4-chlorophenyldichlorophosphine 
• 106-39-8 bromochlorobenzene 
• 1079-66-9 chloro-diphenylphosphine 
• 7270-47-5 4-chlorophenylmagnesium iodide 
• 603-35-0 triphenylphosphine 
• 637-87-6 1-Chloro-4-iodobenzene 
• 1213-51-0 (trimethylstannyl)diphenylphosphine 
• 1257322-31-8 H₃B(PPh₂(C₆H₄Cl)) 
• 40841-62-1 (diphenylphosphino)(p-tolyl)methanone 
• 829-85-6 diphenylphosphane 
• 108-90-7 chlorobenzene 
• 29540-84-9 4-chlorophenyl trifluoromethanesulfonate 
• 791-28-6 Triphenylphosphine oxide 
• 106-46-7 para-dichlorobenzene 

Downstream Products

• 68899-57-0 Benzyldiphenyl-p-chlorphenylphosphonium 
• 13271-42-6 -p-chlorphenyl-diphenyl-phosphazin 
• 24764-35-0 Diphenyl-(4-chlor-phenyl)-<2,7-dibrom-fluorenyliden-(9)>-phosphoran 
• 34303-18-9 1-chloro-4-(diphenylphosphinoyl)benzene 
• 93581-92-1 Pd(SCN)2((ClC₆H₄)P(C₆H₅)2)2 
• 84914-24-9 Pd((C₆H₅)2P(C₆H₄Cl))2Cl₂ 
• 86528-29-2 [Pt2H(PPh2(4-ClC6H4))(μ-dppm)]PF6 
• 1333-74-0 hydrogen 
• 147999-73-3 p-chlorophenyldiphenylphosphanegold(I) chloride 
• 84914-24-9 PdCl₂{(C₆H₅)2P(C₆H₄Cl)}2 
• 1474-08-4 (4-chlorophenyl)diphenylphosphine sulfide 

Relevant academic research and scientific papers

Palladium-Catalyzed C-P(III) Bond Formation by Coupling ArBr/ArOTf with Acylphosphines

Palladium-catalyzed C-P bond formation reaction of ArBr/ArOTf using acylphosphines as differential phosphination reagents is reported. The acylphosphines show practicable reactivity with ArBr and ArOTf as the phosphination reagents, though they are inert to the air and moisture. The reaction affords trivalent phosphines directly in good yields with a broad substrate scope and functional group tolerance. This reaction discloses the acylphosphines' capability as new phosphorus sources for the direct synthesis of trivalent phosphines.

Diverse C-P Cross-Couplings of Arylsulfonium Salts with Diarylphosphines via Selective C-S Bond Cleavage

Diverse C-P cross-couplings of arylthianthrenium salts with diarylphosphines producing various triarylphosphines via highly selective C-S bond cleavage are reported. In the absence of catalyst, the reaction of arylthianthrenium salts with diarylphosphines undergoes phosphinative ring opening exclusively via the cleavage of an endocyclic C-S bond of a thianthrene skeleton. The use of a palladacycle catalyst under otherwise the same conditions enables the phosphination via the cleavage of an exocyclic C-S bond with significantly higher speed.

Ready Approach to Organophosphines from ArCl via Selective Cleavage of C-P Bonds by Sodium

The preparation, application, and reaction mechanism of sodium phosphide R2PNa and other alkali metal phosphides R2PM (M = Li and K) have been studied. R2PNa could be prepared, accurately and selectively, via the reactions of SD (sodium finely dispersed in mineral oil) with phosphinites R2POR′ and chlorophosphines R2PCl. R2PNa could also be prepared from triarylphosphines and diarylphosphines via the selective cleavage of C-P bonds. Na was superior to Li and K for these reactions. R2PNa reacted with a variety of ArCl to efficiently produce R2PAr. ArCl is superior to ArBr and ArI since they only gave low yields of the products. In addition, Ph2PNa is superior to Ph2PLi and Ph2PK since Ph2PLi did not produce the coupling product with PhCl, while Ph2PK only gave a low yield of the product. An electron-withdrawing group on the benzene ring of ArCl greatly accelerated the reactions with R2PNa, while an alkyl group reduced the reactivity. Vinyl chloride and alkyl chlorides RCl also reacted efficiently. While t-BuCl did not produce the corresponding product, admantyl halides could give the corresponding phosphine in high yields. A wide range of phosphines were prepared by this method from the corresponding chlorides. Unsymmetric phosphines could also be conveniently generated in one pot starting from Ph3P. Chiral phosphines were also obtained in good yields from the reactions of menthyl chlorides with R2PNa. Possible mechanistic pathways were given for the reductive cleavage of R3P by sodium generating R2PNa and the substitution reactions of R2PNa with ArCl generating R2PAr.

An efficient heterogeneous cross-coupling of aryl iodides with diphenylphosphine catalyzed by copper (I) immobilized in MCM-41

The heterogeneous cross-coupling reaction of aryl iodides with diphenylphosphine was achieved in toluene at 115?°C in the presence of 10?mol% of phenanthroline-functionalized MCM-41-supported copper (I) complex (Phen-MCM-41-CuI) with Cs2CO3 as base, yielding various unsymmetric triarylphosphines in good to excellent yields. This protocol can tolerate a wide range of functional groups and does not need the use of expensive additives or harsh reaction conditions. This heterogeneous Cu (I) catalyst exhibited the same catalytic activity as homogeneous CuI/Phen system, and could easily be recovered by a simple filtration of the reaction solution and recycled up to seven times without significant loss of activity.

A practical synthesis of unsymmetrical triarylphosphines by heterogeneous palladium(0)-catalyzed cross-coupling of aryl iodides with diphenylphosphine

The heterogeneous cross-coupling reaction of aryl iodides with diphenylphosphine was achieved in DMAc at 130 °C in the presence of 1.0 mol% of MCM-41-supported tridentate nitrogen palladium(0) complex [MCM-41-3N-Pd(0)] with KOAc as base, yielding a variety of unsymmetrical triarylphosphines in good to excellent yields. The turnover frequency (TOF) of the catalyst can reach 30.67 h?1. This new heterogeneous palladium(0) catalyst could easily be prepared by a simple procedure from commercially readily available reagents, and exhibited the same catalytic activity as homogeneous Pd(OAc)2 or Pd(PPh3)4, and could be recovered by filtration of the reaction solution and recycled at least seven times without significant loss of catalytic activity.

Differentially Substituted Phosphines via Decarbonylation of Acylphosphines

A new route to phosphines was developed by a method that features a "pre-join and transform" process that proceeds via acylphosphine intermediates that may be readily prepared from carboxylic acids and disubstituted phosphines. The efficient decarbonylations of these acylphosphines using a nickel catalyst delivered the corresponding phosphines. This method shows that the carboxyl group can play a role similar to halides or triflates for introducing a substituted phosphorus atom on an aromatic ring.

Method for synthesizing phosphorus-containing organic matter

The invention provides a method for synthesizing a phosphorus-containing organic matter; the method comprises: under the protection of an inert gas, subjecting halohydrocarbon or sulfonate shown in formula 1 and an acylphosphine compound shown in formula 2 to coupling reaction in the presence of a transition metal catalyst, a solvent and an additive to obtain a trivalent phosphine compound shown in formula 3, described in the description, wherein each of R1, R2 and R3 is independently at least one of C1-C16 alkyl, C6-C20 aryl and C4-C15 heterocyclic aryl; the additive is an inorganic base or organic base; in the method, the acylphosphine compound is used as a safety phosphine reagent used for performing transition metal catalyzed carbon-phosphorus bond coupling reaction so as to synthesize the phosphorus-containing organic matter; the method has high yield and good safety and convenience.

Palladium-catalyzed C–P(III) bond formation reaction with acylphosphines as phosphorus source

Palladium-catalyzed C–P(III) bond formation reaction employing acylphosphines as the phosphorus source was developed. Under the optimized conditions, acylphosphines could react with aryl halides directly affording trivalent phosphines in up to 94% yield.

General and selective copper-catalyzed reduction of tertiary and secondary phosphine oxides: Convenient synthesis of phosphines

Novel catalytic reductions of tertiary and secondary phosphine oxides to phosphines have been developed. Using tetramethyldisiloxane (TMDS) as a mild reducing agent in the presence of copper complexes, PO bonds are selectively reduced in the presence of other reducible functional groups (FGs) such as ketones, esters, and olefins. Based on this transformation, an efficient one pot reduction/phosphination domino sequence allows for the synthesis of a variety of functionalized aromatic and aliphatic phosphines in good yields.

Novel phosphite palladium complexes and their application in C-P cross-coupling reactions

A mono- and a 1,3-bis-phosphite arene ligand based on 2,2′-biphenol have been synthesized in order to study the synthesis of the corresponding palladium(II) complexes starting from different Pd precursors. Novel bis-phosphite palladium complex 1 [PdCl2(L)2] (L = dibenzo[d,f][1,3,2]dioxaphosphepin, 6-phenoxy), C,P-chelate bonded monophosphite palladium complex 2 [Pd(κ2-L)(μ-Cl)]2, and PCP-pincer palladium complex 3 have been prepared from these ligands in promising to excellent yields (50-95%). Additionally, complexes 1 and 3 have been characterized by X-ray crystal structure determinations. The application of 2,6-bis-phosphite pincer palladium(II) complex 3 in C-P cross-coupling between diphenylphosphine-borane and a wide range of various aryl iodides under very mild conditions is reported. Kinetic investigations indicate that 3 merely acts as a pre-catalyst and that Pd nanoparticles are the actual catalytically active species.