14221-02-4

Basic information

• Product Name: Tetrakis(triphenylphosphine)platinum
• Synonyms: PLATINUM-TETRAKIS(TRIPHENYLPHOSPHINE);TETRAKIS(TRIPHENYLPHOSPHINE)PLATINUM;TETRAKIS(TRIPHENYLPHOSPHINE)PLATINUM(0);Platinum(0)tetrakis(triphenylphosphine);Tetrakis(triphenylphosphine)platinum(0),98%;( beta-4)-platinu;Tetrakis-(triphenylphosphino)-platinum;Tetrakis(triphenylphosphine)platinum(0), Pt 15.2% min
• CAS NO: 14221-02-4
• Molecular Formula: C₇₂H₆₀P₄Pt
• Molecular Weight: 1244.219844
• EINECS: 238-087-4
• Product Categories: metal-phosphine complexes;Pt
• Mol File: 14221-02-4.mol

Chemical Properties

• Melting Point: 122 °C
• Boiling Point: 360ºC at 760 mmHg
• Flash Point: 181.7ºC
• Appearance: Clear/Liquid
• Storage Temp.: 0-6°C
• Solubility: Soluble in benzene
• Water Solubility: INSOLUBLE
• Sensitive: Air Sensitive
• CAS DataBase Reference: Tetrakis(triphenylphosphine)platinum(CAS DataBase Reference)
• NIST Chemistry Reference: Tetrakis(triphenylphosphine)platinum(14221-02-4)
• EPA Substance Registry System: Tetrakis(triphenylphosphine)platinum(14221-02-4)

Safety Data

• Safety Statements: 22-24/25
• WGK Germany: 3
• F: 8-10-23
• TSCA: Yes
• Hazardous Substances Data: 14221-02-4(Hazardous Substances Data)

Usage

Uses

Used in Catalysts:
Tetrakis(triphenylphosphine)platinum is used as a catalyst in the hydrosilation and oxidation reactions. It plays a crucial role in facilitating these reactions, leading to the formation of desired products with high efficiency and selectivity.
Used in Metal & Specialty Catalysts Industry:
In the Metal & Specialty Catalysts Industry, Tetrakis(triphenylphosphine)platinum is employed as a catalyst for various chemical processes. Its unique properties make it a valuable component in the development of new and improved catalysts for a range of applications.
Used in Products & Industries:
Tetrakis(triphenylphosphine)platinum is utilized in the production of various products and across different industries due to its catalytic capabilities. It contributes to the advancement of chemical processes and the synthesis of new compounds, making it an essential component in the development of innovative materials and technologies.

Purification Methods

It forms yellow crystals on adding hexane to a cold saturated solution in *C6H6. It is soluble in *C6H6 and CHCl3 but insoluble in EtOH and hexane. A less pure product is obtained if it is crystallised by adding hexane to a CHCl3 solution. It is stable in air for several hours and completely stable under N2. [Malatesta & Cariello J Am Chem Soc 2323 1958, Beilstein 16 IV 955.]

InChI:InChI=1/4C18H15P.Pt/c4*1-4-10-16(11-5-1)19(17-12-6-2-7-13-17)18-14-8-3-9-15-18;/h4*1-15H;/q;;;;-4/p+4/rC72H64P4Pt/c1-13-37-61(38-14-1)73(62-39-15-2-16-40-62,63-41-17-3-18-42-63)77(74(64-43-19-4-20-44-64,65-45-21-5-22-46-65)66-47-23-6-24-48-66,75(67-49-25-7-26-50-67,68-51-27-8-28-52-68)69-53-29-9-30-54-69)76(70-55-31-10-32-56-70,71-57-33-11-34-58-71)72-59-35-12-36-60-72/h1-60,73-76H

Upstream product

• 13517-35-6 tris(triphenylphosphine)platinum⁽⁰⁾ 
• 74-85-1 ethene 
• 12120-15-9 ethylenebis(triphenylphosphine)platinum⁽⁰⁾ 
• 10199-34-5 bis(triphenylphosphine)platinum(II) dichloride 
• 10025-65-7 platinum(II) chloride 
• 594-09-2 trimethylphosphane 
• 215435-76-0 Pt(CH₂CHCHCH₃)Cl(P(C₆H₅)3)2 
• 603-35-0 triphenylphosphine 
• 12130-66-4 bis(cycloocta-1,5-diene)platinum⁽⁰⁾ 
• 1148055-74-6 platinum bis(triphenylstibine) dichloride 
• 10025-99-7 potassium tetrachloroplatinate(II) 
• 2622-14-2 tricyclohexylphosphine 
• 14056-88-3 trans-dichlorobis(triphenylphosphine)platinum(II) 
• 14177-93-6 trans-platinum(triethylphosphine)₂(chloro)₂ 

Downstream Products

• 18517-48-1 Pt(PPh₃)₂Br₂ 
• 10199-34-5 cis-dichlorobis(triphenylphosphine)platinum(II) 
• 631921-83-0 Pt(triphenylphosphine)2F₂ 
• 183903-82-4 {(CH₃)3Sn}2Pt{P(C₆H₅)3}2 
• 89370-87-6 Pt(P(C₆H₅)3)3(PNN(CH₃)C(CH₃)N) 
• 89370-89-8 Pt(P(C₆H₅)3)3((CH₃)N₂C(CH₃)CHP) 
• 174276-83-6 cis-[Pt(η(1)-CH2CCPh)(Cl)(PPh3)2] 
• 1333-74-0 hydrogen 
• 16841-99-9 trans-chlorohydridobis(triphenylphosphine)platinum(II) 
• 7440-06-4 platinum 
• 15614-67-2 (η2-peroxo)bis(triphenylphosphine)platinum 
• 52653-84-6 cis-bis(phenylselenolato)bis(triphenylphosphine)platinum 
• 52690-90-1 trans-[Pt(H)(SePh)(PPh₃)2] 

Relevant articles and documents

The synthesis and vibrational spectra of tetrakistrimethylphosphinenickel(0) and -platinum(0), Ni(PMe3)4 and Pt(PMe3)4

The syntheses of the molecules Ni(PMe3)4 and Pt(PMe3)4 are reported for the first time.The platinum compound is much less stable than the nickel analogue.Raman and i.r. spectra have been obtained for the nickel compound and a complete vibrational assignment is proposed on the basis of Td molecular symmetry.For the platinum compound only the i.r. spectrum has been obtained.

Trivalent Antimony as L-, X-, and Z-Type Ligand: The Full Set of Possible Coordination Modes in Pt-Sb Bonds

In the course of our investigations of the coordination chemistry of trivalent antimony (Sb) compounds, we studied heteronuclear complexes formed in reactions of the compounds RSb(pyS)2 (R = pyS, Ph; pyS- = pyridine-2-thiolate) with [Pt(PPh3)4], i.e., complexes [(R)Sb(μ-pyS)2Pt(PPh3)] (R = pyS, 1; R = Ph, 2). The reaction of 1 with o-chloranil proceeds cleanly with elimination of 2,2′-dipyridyl disulfide and formation of the salt [(PPh3)Pt(μ-pyS)2Sb(μ-pyS)2Pt(PPh3)]+[Sb(C6Cl4O2)2]- (3III), which features the cation 3+. The charge-neutral, unsymmetrically substituted compound [(PPh3)Pt(μ-pyS)2Sb(μ-pyS)2Pt(κS-pyS)] (4) can be accessed by the reaction of 3+ with LipyS. The oxidation of 2 with o-chloranil furnishes the complex [(κ-O,O-C6Cl4O2)PhSb(μ-pyS)2Pt(PPh3)] (5). The oxidation of 1 with PhICl2 afforded the paddlewheel-shaped complex [Sb(μ-pyS)4PtCl] (6). Moreover, compound 6 was obtained by the reaction of Sb(pyS)3 with [PtCl(pyS)(PPh3)]. The polarization of Pt-Sb bonds of compounds 1-6 was investigated by natural localized molecular orbital (NLMO) calculations, which suggest X-type ligand character (covalent Pt-Sb bonds) for 1 and 2, whereas the Sb ligand of 6 reflects Z-type character (dative Pt→Sb bonds). In 3+, 4, and 5, high contributions of the reverse, i.e., L-type (dative Pt←Sb bonds), were observed. In conjunction with the results of NLMO analyses, 121Sb M?ssbauer spectroscopy proves that complexes 1-6 represent essentially trivalent Sb complexes with either a free lone pair (LP) at the Sb atom (1, 2, and 6) or LP character involved in L-type Pt←Sb coordination (3+, 4, and 5).

Method for preparing palladium (0) or platinum (0) composite compound from triphenylphosphine

The invention provides a method for preparing a palladium (0) or platinum (0) composite compound from triphenylphosphine; with use of palladium chloride (PdCl2) or hydrochloroplatinic acid (H2PtCl6.xH2O) as a starting material, preliminary preparation reaction is not needed, and commercially purchased palladium chloride or hydrochloroplatinic acid can be directly used for reaction. The reaction process is simple, all the reactions are carried out in a same reactor, separation of intermediate products is not needed, and the loss is reduced; the yield of target products is high; the recovery problem of reaction residues is simplified. The product has high reactivity and catalytic activity in various reactions, and has broad application prospects.

Mechanistic study of β-hydrogen elimination from organoplatinum(II) enolate complexes

A detailed mechanistic investigation of the thermal reactions of a series of bisphosphine alkylplatinum(II) enolate complexes is reported. The reactions of methylplatinum enolate complexes in the presence of added phosphine form methane and either free or coordinated enone, depending on the steric properties of the enone. Kinetic studies were conducted to determine the relationship between the rates and mechanism of β-hydrogen elimination from enolate complexes and the rates and mechanism of β-hydrogen elimination from alkyl complexes. The rates of reactions of the enolate complexes were inversely dependent on the concentration of added phosphine, indicating that β-hydrogen elimination from the enolate complexes occurs after reversible dissociation of a phosphine. A normal, primary kinetic isotope effect was measured, and this effect was consistent with rate-limiting β-hydrogen elimination or C-H bond-forming reductive elimination to form methane. Reactions of substituted enolate complexes were also studied to determine the effect of the steric and electronic properties of the enolate complexes on the rates of β-hydrogen elimination. These studies showed that reactions of the alkylplatinum enolate complexes were retarded by electron-withdrawing substituents on the enolate and that reactions of enolate complexes possessing alkyl substituents at the β-position occurred at rates that were similar to those of complexes lacking alkyl substituents at this position. Despite the trend in electronic effects on the rates of reactions of enolate complexes and the substantial electronic differences between an enolate and an alkyl ligand, the rates of decomposition of the enolate complexes were similar to those of the analogous alkyl complexes. To the extent that the rates of reaction of the two types of complexes are different, those involving β-hydrogen elimination from the enolate ligand were faster. A difference between the rate-determining steps for decomposition of the two classes of complexes and an effect of stereochemistry on the selectivity for β-hydrogen elimination are possible origins of the observed phenomena.

Si-H bond activation by (Ph3P)2Pt(η2- C2H4) in dihydrosilicon tricycles that also contain O and N heteroatoms

Several tricyclic phenoxasilin and phenazasiline heterocycles were synthesized from the corresponding 2,2′-dilithio-diphenyl ether or diphenyl amine precursor and silicon tetrachloride (or trichlorosilane) followed by reduction with lithium aluminum hydride [H2SiAr2: Ar2 = C12H8O (1); Ar2 = C 14H12O (2); Ar2 = C13H11N (3); Ar2 = C15H15N (4); Ar2 = C13H9Br2N (5)]. The reactivity of hydrosilanes 1-5 with (Ph3P)2Pt(η2-C2H 4) (6) was investigated. At room temperature, mononuclear complexes, (Ph3P)2Pt(H)-(SiAr2H) and (Ph 3P)2Pt(SiAr2H)2, were generally observed by NMR spectroscopy but were too reactive or unstable to isolate. Dinuclear and in some cases trinuclear Pt-Si-containing complexes were observed as the major products from the reactions. Symmetrical dinuclear complexes, [(Ph3P)Pt(μ-η2-H-SiAr2)]2 (8 and 22, respectively), were produced from the reaction of 1 or 3 with 6. In contrast, reaction of silane 2 with 6 produced a trinuclear complex, [(Ph 3P)Pt(μ-SiAr2)]3 (16), as the major product. However, reaction of 4 or 5 with complex 6 produced an unsymmetrical dinuclear complex, [(Ph3P)2Pt(H)(μ-SiAr2)(μ- η2-H-SiAr2)Pt(PPh3)] (26 and 30, respectively), as the major component. The molecular structures of a symmetrical (22) and unsymmetrical dinuclear (30) complex as well as a trinuclear (16) complex were determined by X-ray crystallography.

Reaction of silafluorenes with (Ph3P) 2Pt(η2-C2H4): Generation and characterization of Pt-Si monomers, dimers and trimers

The reaction of silafluorene (1; H2SiC12H 8) with (Ph3P)2Pt(η2-C 2H4) (2) at room temperature in C7D8 initially provided the mononuclear complex (Ph3P) 2Pt(H)[Si(H)C12H8] (3), followed by the appearance of the unsymmetrical dinuclear complex (Ph3P) 2(H)Pt(μ-SiC12H8)(μ-η2- HSiC12H8)Pt(PPh3) (4) and finally the novel trinuclear complex [(Ph3P)Pt(μ-SiC12H 8)]3 (5). The three complexes were characterized by multinuclear NMR spectroscopy and by X-ray crystallography (5). The molecular structure of 5 exhibits a nonplanar Pt3Si3 core. When the reaction was conducted at low temperature until the silafluorene was consumed and the mixture then warmed to room temperature, the dinuclear complex 4 could be isolated. The related substituted silafluorene system 3,7-di-tert- butylsilafluorene (6; H2SiC20H24) also reacted with 2 to provide both mono- and dinuclear complexes (7 and 8) analogous to 3 and 4. The dinuclear complex 8 was isolated and crystallographically characterized. Each of the two Pt centers in complex 8 exhibits a unique environment. In solution at low temperature 8 is best described as having one platinum center with a terminal hydride, [Pt(H)(PPh3)2], and the second platinum with a nonclassical [Si...H...Pt(PPh 3)] unit. However, in the solid state, the two hydrides may both adopt a bridging environment. Heating a sample of the unsymmetrical dimer 8 led to the formation of several products, one of which was the trimer 9, analogous to 5.

Reactions of binuclear ruthenium-platinum μ-allenyl complexes with nucleophilic and electrophilic reagents. The characterization of two 1:1 adducts of L(PPh3)Pt(μ-η1:η2α,β-C(Ph)=C=CH2)Ru(CO)Cp (L=PPh3, t-BuNC) and p-toluenesulfonyl isocyanate

Reactions of (PPh3)2Pt(μ-η1:η2α,β-C(R)=C=CH2)Ru(CO)Cp (R=H (1), Ph (2)) with Ph2PCH2CH2CH2PPh2, PEt3 and t-BuNC in THF at -78°C to room temperature afforded the substitution products L2Pt(μ-η1:η2α,β-C(R)=C=CH2)Ru(CO)Cp (R=H, L2=Ph2PCH2CH2CH2PPh2 (3), R=Ph, L2=Ph2PCH2CH2CH2PPh2 (4), R=H, L2=2PEt3 (5), R=Ph, L2=PPh3 and t-BuNC (6)). No reaction was observed for 1 with Et2NH or C6H11NH2 and 2 with p-TolS(O)2NH2 in THF at reflux temperature. Complex 2 reacted with p-TolS(O)2NCO (TSI) in toluene at -78°C to room temperature to yield two 1:1 addition products of the reactants: the γ-carbon substituted μ-allenyl (PPh3)2Pt(μ-η1:η2α,β-C(Ph)=C=CHC(O)NHS(O)2Tol-p) (7) and the [3+2] cycloadduct (PPh3)2Pt(μ-η1:η2-C=C(Ph)N(S(O)2Tol-p)C(O)CH2)Ru(CO)Cp (8). Complexes 4 and 6 afforded with TSI, under essentially similar conditions, only [3+2] cycloadducts, L2Pt(μ-η1:η2-C=C(Ph)N(S(O)2Tol-p)C(O)CH2)Ru(CO)Cp (L2=Ph2PCH2CH2CH2PPh2 (9), PPh3 and t-BuNC (10)). All products were characterized by a combination of IR and NMR (1H, 13C{1H} and 31P{1H}) spectroscopy, FAB MS and elemental analysis. The structures of 7 (as 7·C3H6O) and 10 were determined by single-crystal X-ray diffraction analysis. Reactions of 2 with trans-NCCH=CHCN (L) and of 1 with the alkynes MeO2CC?CCO2Me, MeO2CC?CMe, PhC?CH and PhC?CPh (L) resulted in the formation of the mononuclear metal complexes Cp(CO)2RuC(R)=C=CH2 (R=H, Ph) and (PPh3)2PtL. The reverse of this fragmentation reaction occurred when Cp(CO)2RuCH=C=CH2 was treated with (PPh3)2Pt(PhC?CPh). No reaction was observed between 2 and each (CN)2C=CPh2 and MeS(O)2NSO in benzene or toluene on heating. The η1-allenyl Cp(CO)2RuC(Ph)=C=CH2, obtained in this study, is a new compound.

Unexpected substitution reactions of bis(phosphine)platinum ethene complexes

Reaction of [Pt(C2H4)(PR3)2] (R = Ph or C6H4Me-4) with moderately bulky phosphines at low temperatures did not give the expected tris- or tetrakis-phosphine complexes. Instead, mixed-phosph

Thermal analysis of coordination compounds. Part 3. Thermal decomposition of platinum complexes containing triphenylphosphine, triphenylarsine and triphenylstibine

Studies by thermogravimetric analysis (TG) and differential thermal analysis (DTA) of the complexes [PtCl2L2] (L is PPh3, AsPh3, SbPh3), [PtLn] (n = 3, L is SbPh3; n= 4, L is PPh3, AsPh3); [(PtL3)2N2]; [(PtL3)2C2] and [Pt(CO)2L2] (L is SbPh3) are described. Analysis of the TG and DTA curves showed that Pt(II) complexes of the type [PtCl2L2] have a higher thermal stability than the corresponding Pt(0) complexes of the type [PtLn], with the exception of [Pt(SbPh3)3], which is more stable than [PtCl2(SbPh3)2]. Thermal stabilities of each of the complexes are compared with those of the others in the series. Mechanisms of thermal decomposition of complexes of the types [PtCl2L2] and [PtLn] are proposed. Residues of the samples were characterized by chemical tests and IR spectroscopy. The residue from the thermal decomposition of [PtCl2L2] (L is PPh3, AsPh3)and [Pt(PPh3)4] is metallic platinum. For [Pt(AsPh3)4] the residue is a mixture of Pt and As, whereas for the complexes containing SbPh3 the re sidues are mixtures of Pt and Sb. In these cases, the proportional contents of Pt and As or Pt and Sb correspond to the stoichiometry of these elements in the respective complexes. The complexes [Pt(SbPh3)3]2N2, [Pt(SbPh3)3]2C2 lose N2 or the ethynediyl group at 130-150°C are transformed into [Pt(SbPh3)3].

Synthesis and Reactivity of N-Acetylamino acidate(2-) and Related Complexes of Platinum(II)

Treatment of the complexes (L = P-donor ligand) with the N-acetyl derivatives of the amino acids glycine, DL-alanine, DL-methionine or L-phenylalanine in the presence of an excess of silver(I) oxide in refluxing dichloromethane affords PtN(COM