Phenylsilane

Base Information

• Chemical Name: Phenylsilane
• CAS No.: 694-53-1
• Molecular Formula: C6H8Si
• Molecular Weight: 108.215
• Hs Code.: 29319090
• European Community (EC) Number: 211-772-5
• NSC Number: 179699
• UNII: P2EX7Q1UYS
• DSSTox Substance ID: DTXSID70870757
• Wikipedia: Phenylsilane
• Mol file: 694-53-1.mol

Synonyms:Phenylsilane;694-53-1;Silylbenzene;Benzene, silyl-;phenylsilicon;SILANE, PHENYL-;Fenylsilan;Fenylsilan [Czech];Phenylsilane, silyl-;EINECS 211-772-5;P2EX7Q1UYS;NSC 179699;NSC-179699;phenylsilan;monophenylsilane;Silane, phenyl-,;[Si]c1ccccc1;MFCD00013478;NSC179699;Phenylsilane, 97%;UNII-P2EX7Q1UYS;C6-H8-Si;DTXSID70870757;CHEBI:172874;BBL103617;STL557427;AKOS006222506;SB40748;SIP-6750.0;AS-48901;LS-145232;AM20041020;CS-0006214;P1291;EN300-76473;S13600;Z-6047;A836499

Chemical Property of Phenylsilane

Chemical Property:

• Appearance/Colour: clear colorless liquid
• Vapor Pressure: 19.2mmHg at 25°C
• Melting Point: -64 to -68°C
• Refractive Index: n20/D 1.510(lit.)
• Boiling Point: 119.3 °C at 760 mmHg
• Flash Point: 25.9 °C
• PSA: 0.00000
• Density: 0.877 g/mL at 25 °C(lit.)
• LogP: -0.32270
• Storage Temp.: Flammables area
• Sensitive.: Air & Moisture Sensitive
• Water Solubility.: Contact with water releases a flammable alcohol. Soluble in water (Contact with water releases flammable gases), and most common
• Hydrogen Bond Donor Count: 0
• Hydrogen Bond Acceptor Count: 0
• Rotatable Bond Count: 0
• Exact Mass: 105.016051694
• Heavy Atom Count: 7
• Complexity: 46.1

Purity/Quality:

min 99% ^*data from raw suppliers

Phenylsilane ^*data from reagent suppliers

Safty Information:

• Pictogram(s): F,Xn
• Hazard Codes: F,Xn
• Statements: 11-14/15-20/22-36/37/38
• Safety Statements: 16-43

MSDS Files:

SDS file from LookChem

Total 1 MSDS from other Authors

Useful:

• Canonical SMILES: C1=CC=C(C=C1)[Si]
• Uses: phenylsilane is used as a pharmaceutical intermediate. Phenylsilane (PhSiH3) may be used as a reducing agent for the partial reduction of phosphine oxide groups in poly(4,4′-diphenylphenylphosphine oxide) (PAPO) to phosphine. It can also undergo photopolymerization with methyl methacrylate(MMA) to form poly(MMA) containing SiH groups. PhSiH3 may be used as a silicon source to synthesize crystalline Si nanowires via Au-nanocrystal-seeded supercritical fluid-liquid-solid (SFLS) synthesis.

Technology Process of Phenylsilane

There total 29 articles about Phenylsilane which guide to synthetic route it. The literature collected by LookChem mainly comes from the sharing of users and the free literature resources found by Internet computing technology. We keep the original model of the professional version of literature to make it easier and faster for users to retrieve and use. At the same time, we analyze and calculate the most feasible synthesis route with the highest yield for your reference as below:

synthetic route:

Reference yield: 86.0%

dmap (1122-58-3) + C53H101B2Co2P5Si2 → phenylsilane (694-53-1) + C54H101B2Co2N2P5Si

Guidance literature:

In toluene; at 65 ℃; for 4h; Solvent; Inert atmosphere; Glovebox;

DOI:10.1021/jacs.9b04265

Reference yield: 84.0%

Phenyltrichlorosilane (98-13-5) → phenylsilane (694-53-1)

Guidance literature:

With lithium aluminium tetrahydride; In diethyl ether;

DOI:10.1055/s-1984-30907

Reference yield: 79.0%

methylmagnesium bromide (75-16-1) + sodium bis(benzene-1,2-diolatophenyl)silicate (6157-41-1) → Dimethylphenylsilane (766-77-8) + phenylsilane (694-53-1) + methylphenylsilane (766-08-5,146088-00-8)

Guidance literature:

In diethyl ether; at 0 ℃; for 2.5h;

DOI:10.1246/bcsj.61.101

upstream raw materials:

diphenylsilane

Phenyltrichlorosilane

triethoxyphenylsilane

methyllithium

Downstream raw materials:

(1-octyl)(phenyl)silane

1-phenylsilanyl-3-trimethylsilanyloxy-propane

1,1,1,3,3,3-hexamethyl-2-(3-phenylsilanyl-propyl)-disilazane

bromo-phenyl-silane

Refernces

Efficient kinetic resolution in the asymmetric hydrosilylation of imines of 3-substituted indanones and 4-substituted tetralones

10.1021/jo991328h

The research focuses on the efficient kinetic resolution in the asymmetric hydrosilylation of imines of 3-substituted indanones and 4-substituted tetralones, utilizing a chiral titanocene catalyst. The purpose of this study was to achieve high enantiomeric excess (ee) and diastereomeric purity in the synthesis of ketones and amines, which are crucial for the production of bioactive and pharmaceutically interesting molecules, such as the antidepressant sertraline. The researchers successfully demonstrated that N-methyl imines of 4-substituted tetralones could be resolved to yield ketones with high ee's and amine products with high diastereomeric and enantiomeric purity. Key chemicals used in the process include phenylsilane as the stoichiometric reductant, (EBTHI)titanocene catalyst, and various imine substrates derived from 3-substituted indanones and 4-substituted tetralones. The study concluded that the methodology could be applied to the enantiomeric synthesis of sertraline, an important antidepressant, with high diastereoselectivity and enantioselectivity.

Control of Selectivity through Synergy between Catalysts, Silanes, and Reaction Conditions in Cobalt-Catalyzed Hydrosilylation of Dienes and Terminal Alkenes

10.1021/acscatal.6b03373

The research study on the control of selectivity in cobalt-catalyzed hydrosilylation of dienes and terminal alkenes through the synergy between catalysts, silanes, and reaction conditions. The purpose of the study was to develop a method for highly selective anti-Markovnikov hydrosilylation of terminal double bonds in 1,3- and 1,4-dienes, as well as terminal alkenes, using readily accessible (i-PrPDI)CoCl2 as the catalyst and primary or secondary silanes such as PhSiH3, Ph2SiH2, and PhSi(Me)H2. The research concluded that by optimizing the reaction conditions, it was possible to achieve high selectivity in anti-Markovnikov hydrosilylation, with the product ratio favoring the anti-Markovnikov product as the size of the 2,6-substituents in the iminoylaryl group increased.

Reductive Carbocyclization of Homoallylic Alcohols to syn-Cyclobutanes by a Boron-Catalyzed Dual Ring-Closing Pathway

10.1002/anie.201713285

The study titled "Reductive Carbocyclization of Homoallylic Alcohols to syn-Cyclobutanes via Boron-Catalyzed Dual Ring-Closing Pathway" explores a novel method for synthesizing 1,2-disubstituted arylcyclobutanes through an organoborane-catalyzed reductive carbocyclization process. The key chemicals involved are homoallylic alcohols and their O-silyl ethers, which act as the substrates for the cyclobutanation reaction. Hydrosilanes, specifically EtMe2SiH and PhSiH3, serve as reducing agents, while B(C6F5)3 functions as the catalyst. The reaction proceeds in a cis-selective manner under mild conditions, yielding cyclobutanes with high efficiency and excellent selectivity. Mechanistic studies, including deuterium scrambling, Hammett studies, and DFT calculations, support a dual ring-closing pathway involving carbocation rearrangements. The study demonstrates the versatility of the method by testing various substrates, including those with functional groups like phenoxy and thioether, and shows that the olefinic geometry of the substrates does not affect the stereochemistry of the product. The findings highlight a powerful alternative to conventional methods for synthesizing four-membered carbocycles, offering a mild, efficient, and selective route to produce cyclobutanes and cyclopentanes.

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