7650-91-1

Basic information

• Product Name: BENZYLDIPHENYLPHOSPHINE
• Synonyms: Benzyldiphenylphosphine,98%;BENZYLDIPHENYLPHOSPHINE;Benzyldiphenylphosphine,99%;Diphenyl(phenylmethyl)phosphine;Diphenylbenzylphosphine;Benzyldiphenylphosphine,97%
• CAS NO: 7650-91-1
• Molecular Formula: C₁₉H₁₇P
• Molecular Weight: 276.31
• EINECS: 1312995-182-4
• Product Categories: organophosphorus ligand;Achiral Phosphine;Aryl Phosphine;Basic Phosphine LigandsCatalysis and Inorganic Chemistry;Catalysis and Inorganic Chemistry;Cross-Coupling;Phosphine Ligands;Phosphorus Compounds
• Mol File: 7650-91-1.mol

Chemical Properties

• Melting Point: 77-83 °C(lit.)
• Boiling Point: 399.6 °C at 760 mmHg
• Flash Point: 206.2 °C
• Appearance: White to off-white/Powder
• Vapor Pressure: 3.12E-06mmHg at 25°C
• Storage Temp.: Inert atmosphere,Room Temperature
• Water Solubility: Slightly soluble in water.
• Sensitive: Air Sensitive
• CAS DataBase Reference: BENZYLDIPHENYLPHOSPHINE(CAS DataBase Reference)
• NIST Chemistry Reference: BENZYLDIPHENYLPHOSPHINE(7650-91-1)
• EPA Substance Registry System: BENZYLDIPHENYLPHOSPHINE(7650-91-1)

Safety Data

• Hazard Codes: Xn
• Statements: 36/37/38-22
• Safety Statements: 37/39-26
• WGK Germany: 3
• Hazardous Substances Data: 7650-91-1(Hazardous Substances Data)

Usage

Chemical Properties

White to off-white powder

Uses

Different sources of media describe the Uses of 7650-91-1 differently. You can refer to the following data:
1. suzuki reaction
2. Employed as a catalyst for Suzuki cross-coupling and antiarthritic agent (inhibitor of cathepsin B). It is also used as catalyst in pharmaceutical research.

InChI:InChI=1/C19H17P/c1-4-10-17(11-5-1)16-20(18-12-6-2-7-13-18)19-14-8-3-9-15-19/h1-15H,16H2

Upstream product

• 1100-88-5 benzyltriphenylphosphonium chloride 
• 19493-09-5 Methylenetriphenylphosphorane 
• 4525-46-6 benzyltrimethylammonium iodide 
• 4376-01-6 sodium diphenylphosphide 
• 80359-58-6 C₁₉H₁₆CsP 
• 108-91-8 cyclohexylamine 
• 100-44-7 benzyl chloride 
• 1079-66-9 chloro-diphenylphosphine 
• 4545-85-1 benzyldichlorophosphane 
• 591-51-5 phenyllithium 
• 829-85-6 diphenylphosphane 
• 100-39-0 benzyl bromide 
• 603-35-0 triphenylphosphine 
• 57170-64-6 1-bromo-2-(diphenylphosphinomethyl)benzene 

Downstream Products

• 105069-47-4 <2-Hydroxy-aethyl>-diphenyl-benzyl-phosphonium 
• 33417-25-3 Benzylbenzylidendiphenylphosphoran 
• 33417-24-2 diphenyldibenzylphosphonium chloride 
• 53201-22-2 Allyl-benzyl-diphenyl-phosphonium-bromid 
• 124730-74-1 N-benzoyl-P-benzyldiphenyl-λ⁵-phosphazene 
• 134403-72-8 4-(Benzyldiphenylphosphonio)benzo-15-crown-5 bromide 
• 124730-76-3 P-benzyldiphenyl-N-ethoxycarbonyl-λ⁵-phosphazene 
• 115287-27-9 C₂₇H₂₄NO₂P 
• 134580-17-9 4',4''-bis(diphenylbenzylphosphonium)dibenzo-18-crown-6 diiodide 
• 134580-18-0 4',5''-bis(diphenylbenzylphosphonium)dibenzo-18-crown-6 diiodide 
• 80359-58-6 C₁₉H₁₆CsP 
• 108-91-8 cyclohexylamine 
• 95499-52-8 benzyl(diphenyl)<3-bromo-6-(4-diethylaminophenylazo)phenyl>phosphonium bromide 
• 134403-71-7 4-(Benzyldiphenylphosphinio)benzo-12-crown-4 bromide 

Relevant articles and documents

Phosphastannirane: A phosphorus/tin(II) lewis pair that undergoes alkyne and alkene addition

Bermuda triangle: The first molecule containing a cyclic three-membered Sn-C-P ring has been synthesized and characterized. This SnII-P Lewis pair reacts at room temperature with alkynes and pentene to give the five-membered cyclic addition products. In the case of pentene, this reaction is reversible at room temperature. Trip=2,4,6-iPr3C6H 2. Copyright

Visible-Light-Promoted Unsymmetrical Phosphine Synthesis from Benzylamines

Herein, by applying visible-light photoredox catalysis, we have achieved the catalytic deaminative alkylation of diphenylphosphine and phenyl phosphine with benzylamine-derived Katritzky salts at room temperature. The use of Eosin Y as photoredox catalyst and visible light can largely promote the reaction. A series of unsymmetrical tertiary phosphines were successfully synthesized, including phosphines with three different substituents that are otherwise difficult to obtain.

A Lewis Base Nucleofugality Parameter, NFB, and Its Application in an Analysis of MIDA-Boronate Hydrolysis Kinetics

The kinetics of quinuclidine displacement of BH3 from a wide range of Lewis base borane adducts have been measured. Parameterization of these rates has enabled the development of a nucleofugality scale (NFB), shown to quantify and predict the leaving group ability of a range of other Lewis bases. Additivity observed across a number of series R′3-nRnX (X = P, N; R′ = aryl, alkyl) has allowed the formulation of related substituent parameters (nfPB, nfAB), providing a means of calculating NFB values for a range of Lewis bases that extends far beyond those experimentally derived. The utility of the nucleofugality parameter is explored by the correlation of the substituent parameter nfPB with the hydrolyses rates of a series of alkyl and aryl MIDA boronates under neutral conditions. This has allowed the identification of MIDA boronates with heteroatoms proximal to the reacting center, showing unusual kinetic lability or stability to hydrolysis.

Versatile Visible-Light-Driven Synthesis of Asymmetrical Phosphines and Phosphonium Salts

Asymmetrically substituted tertiary phosphines and quaternary phosphonium salts are used extensively in applications throughout industry and academia. Despite their significance, classical methods to synthesize such compounds often demand either harsh reaction conditions, prefunctionalization of starting materials, highly sensitive organometallic reagents, or expensive transition-metal catalysts. Mild, practical methods thus remain elusive, despite being of great current interest. Herein, we describe a visible-light-driven method to form these products from secondary and primary phosphines. Using an inexpensive organic photocatalyst and blue-light irradiation, arylphosphines can be both alkylated and arylated using commercially available organohalides. In addition, the same organocatalyst can be used to transform white phosphorus (P4) directly into symmetrical aryl phosphines and phosphonium salts in a single reaction step, which has previously only been possible using precious metal catalysis.

Bis(alkyl) scandium and yttrium complexes coordinated by an amidopyridinate ligand: Synthesis, characterization and catalytic performance in isoprene polymerization, hydroelementation and carbon dioxide hydrosilylation

New neutral bis(alkyl) Sc and Y complexes [N,Npy,N-]Ln(CH2SiMe3)2(THF)n [n = 0, Ln = Sc (1Sc), Y (1Y); n = 1, Ln = Y (1YTHF)] stabilized by a tridentate monoanionic amidopyridinate ligand were straightforwardly prepared by alkane elimination, upon mixing ligand [N,Npy,N-]H and metal precursor Ln(CH2SiMe3)3(THF)2 in toluene at 0 °C. Depending on the work-up conditions, yttrium bis(alkyl)s were isolated as either a pentacoordinate Lewis base free complex [N,Npy,N-]Y(CH2SiMe3)2 (1Y) or as a hexacoordinate THF adduct [N,Npy,N-]Y(CH2SiMe3)2THF (1YTHF). For the smaller Sc ion the only solvent-free complex [N,Npy,N-]Y(CH2SiMe3)2 (1Sc) was isolated as a pentacoordinate species irrespective of the reaction/work-up/crystallization conditions applied. Complexes 1Ln (Ln = Y, Sc) and 1YTHF were scrutinized as pre-catalysts in ternary catalytic systems Ln/borate/AliBu3 (borate = [HNMe2Ph][B(C6F5)4] or [Ph3C][B(C6F5)4]), applied to isoprene (IP) polymerization, providing moderate activity albeit high selectivity with predominant formation of 1,4-cis polyisoprene (up to 99%). The same complexes proved to be effcient catalysts also for the intermolecular hydrolelementation of styrene with various EH sustrates (pyrrolidine, morpholine, Ph2PH, PhPH2, PhSH) affording linear anti-Markovnikov addition products exclusively. After a preliminary activation by B(C6F5)3, selected bis(alkyl) complexes from this series have been finally used as valuable pre-catalysts for the CO2 hydrosylilation to CH4 in the presence of organosilanes as reducing agents (PhMe2SiH, PhSiH3, Et2MeSiH).

Palladium-catalyzed C(sp3)–P(III) bond formation reaction with acylphosphines as phosphorus source

Palladium-catalyzed C(sp3)–P(III) bond formation reaction for alkyl substituted phosphines preparation was developed. In this reaction, various alkyl bromides and limited alkyl chlorides reacted with acylphosphine under relative mild and easily accessible condition, and differential phosphines were afforded in good yields. This reaction made up the application of palladium catalysis in C(sp3)–P(III) bond formation, and indicated a practical application of acylphosphine as a phosphination reagent.

Accessing Ambiphilic Phosphine Boronates through C?H Borylation by an Unforeseen Cationic Iridium Complex

Ambiphilic molecules, which contain a Lewis base and Lewis acid, are of great interest based on their unique ability to activate small molecules. Phosphine boronates are one class of these substrates that have interesting catalytic activity. Direct access to these phosphine boronates is described through the iridium-catalyzed C?H borylation of phosphines. An unconventional cationic iridium catalyst was identified as optimal for a range of phosphines, providing good yields and selectivity across a diverse class of phosphine boronates (isolated as the borane-protected phosphine). A complimentary catalyst system (quinoline-based silane ligand with [(COD)IrOMe]2) was optimal for biphenyl-based phosphines. Selective polyborylation was also shown providing bis- and tris-borylated phosphines. Deprotection of the phosphine boronate provided free ambiphilic phosphine boronates, which do not have detectable interactions between the phosphorus and boron atoms in solution or the solid state.

ORGANIC MAGNESIUM PHOSPHIDE AND MANUFACTURING METHOD THEREOF, ORGANIC MAGNESIUM PHOSPHIDE COMPLEX AND MANUFACTURING METHOD THEREOF, AND MANUFACTURING METHOD OF ORGANIC PHOSPHORUS COMPOUND USING SAID PHOSPHIDE

An organic magnesium phosphide expressed by Formula (1) below and an organic magnesium phosphide complex expressed by Formula (9) below are provided, and a manufacturing method of organic phosphorus compound is characterized in that the above compounds used as a reagent is reacted with an electrophile: wherein R1 and R2 are each independently an aliphatic group, heteroaliphatic group, alicyclic group, or heterocyclic group, and X is chlorine, bromine, or iodine, wherein R3 and R4 are each independently an aliphatic group, heteroaliphatic group, aromatic group, alicyclic group, or heterocyclic group, and X and Y are each independently chlorine, bromine, or iodine.

Alcohol-based Michaelis-Arbuzov reaction: An efficient and environmentally-benign method for C-P(O) bond formation

The famous Michaelis-Arbuzov reaction is extensively used both in the laboratory and industry to manufacture tons of widely-used organophosphoryl compounds every year. However, this method and the modified Michaelis-Arbuzov reactions developed recently still have some limitations. We now report a new alcohol-version of the Michaelis-Arbuzov reaction that can provide an efficient and environmentally-benign method to address the problems of the known Michaelis-Arbuzov reactions. That is, a wide range of alcohols can readily react with phosphites, phosphonites, and phosphinites to give all the three kinds of phosphoryl compounds (phosphonates, phosphinates, and phosphine oxides) using an n-Bu4NI-catalyzed efficient C-P(O) bond formation reaction. This general method can also be easily scaled up and used for further synthetic transformations in one pot.

Electrophilic Phosphonium Cation-Mediated Phosphane Oxide Reduction Using Oxalyl Chloride and Hydrogen

The metal-free reduction of phosphane oxides with molecular hydrogen (H2) using oxalyl chloride as activating agent was achieved. Quantum-mechanical investigations support the heterolytic splitting of H2 by the in situ formed electrophilic phosphonium cation (EPC) and phosphane oxide and subsequent barrierless conversion to the phosphane and HCl. The reaction can also be catalyzed by the frustrated Lewis pair (FLP) consisting of B(2,6-F2C6H3)3 and 2,6-lutidine or phosphane oxide as Lewis base. This novel reduction was demonstrated for triaryl and diaryl phosphane oxides providing access to phosphanes in good to excellent yields (51–93 %).