Phenylsilane

Biographical Sketches

Introduction

Phenylsilane (PhSiH₃) is an organosilane and has been extensively used in organic synthesis as a mild and environmentally benign reducing agent. It is a clear, colorless, volatile liquid which boils at 120 ˚C. [¹] When heated to decomposition it emits acrid smoke and irritating vapors. It reacts violently with water, so the preparation of phenylsilane must be performed in a reaction vessel connected with a vacuum system by a standard ground glass joint. It has been used for the hydrosilylation reduction of ketones and aldehydes to give the corresponding alcohols. [²] It was also found to be an efficient reagent for selective reduction of quinoline to dihydroquinoline, [³] reductive Michael cyclization, [4] and reductive aldol reaction. [5] The reductive coupling of aldimines has been achieved by the use of a combination of PhSiH₃ and titanium isopropoxide [Ti(Oi-Pr)₄]. [6] Reductions of organic halides to dehalogenated ­alkanes with the In(OAc)₃-PhSiH₃ system are readily accomplished. [7] It can also act as an in situ carboxylic acid activating agent to prepare carboxamides and peptides from carboxylic acids and amines. [8]

Phenylsilane is commercially available now. It can be readily prepared by reduction of phenyltrichlorosilane with lithium aluminum hydride in ether. [9]

Abstracts

(A) Reduction of Aldehydes, Ketones, Aldimines, and Ketimines: Matsuoka and Kondo showed that PhSiH3 can efficiently hydrosilylate aldehydes, ketones, aldimines and ketimines to afford the corresponding reduction products in high yields in the presence of catalytic amounts of Ph3P and B(C6F5)3. [¹0]
(B) Direct Reductive Amination of Aldehydes: PhSiH3 can be applied as a mild reducing reagent for direct reductive amination of aldehydes to the corresponding secondary amines catalyzed by oxorhenium complexes [¹¹] or molybdenum dioxide dichloride. [¹²] The protocol tolerates a number of reducible functional groups such as F, Cl, I, OMe, NO2, CO2Me, CN, and double bonds.
(C) Reduction of Sulfoxides to Sulfides: Cabrita et al. showed that a large variety of aryl, aryl alkyl, and alkyl sulfoxides can be reduced with PhSiH3 to the corresponding sulfides catalyzed by HReO4 in THF in high yield. [¹³] This system was also highly chemoselective, tolerating several functional groups such as Cl, NO2, CO2R, and double or triple bonds.
(D) Reduction of Azides to Amines: PhSiH3 is also used as the hydride source for chemoselective reduction of azides to the corresponding amines catalyzed by dioxobis(N,N,-diethyldithiocarbamato) molybdenum complex under neutral reaction conditions. [¹4] This method tolerates a wide variety of reducible functional groups.
(E) 1,4-Reduction and Reductive Aldol Reactions of α-Enones: Miura et al. found that PhSiH3 can serve as a mild reducing agent in 1,4-reduction of certain α-enones, and in intermolecular reductive aldol reactions of α-enones with aldehydes in the presence of a catalytic amount of In(OAc)3 in ethanol at ambient temperature. [¹5]
(F) Dehydration of Amides to Nitriles: A mild method for the catalytic dehydration of aromatic and aliphatic amides using PhSiH3 in the presence of catalytic tetrabutylammonium fluoride (TBAF) has been developed. [¹6]
(G) Selective Deiodination of Iodoheterocycles: Sugimoto et al. reported that nitrogen-containing π-deficient heterocyclic iodides such as iodoquinolines or iodopyridines were deiodinated by treatment with PhSiH3 in the presence of In(OAc)3 and 2,6-lutidine to give the corresponding deiodinated heterocycles. [¹7]
(H) Reduction of Aldehydes and Ketones to Symmetric Ethers: A convenient and practical method for the direct synthesis of symmetric ethers from aldehydes and cyclic ketones using antimony(III) iodide/phenylsilane has been developed. [¹8] Ketones such as acetone or acetophenone did not give the corresponding dialkyl ethers.

References

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References

• 1 Nebergall WH. J. Am. Chem. Soc.  1950,  72:  4702 
  CrossrefSuche in Google Scholar
• 2a Addis D. Zhou SL. Das S. Junge K. Kosslick H. Harloff J. Lund H. Schulz A. Beller M. Chem. Asian J.  2010,  5:  2341 
  Suche in Google Scholar
• 2b Truong TV. Kastl EA. Du GD. Tetrahedron Lett.  2011,  52:  1670 
  Suche in Google Scholar
• 2c Mostefai N. Sirol S. Courmarcel J. Riant O. Synthesis  2007,  1265 
• 3 Voutchkova AM. Gnanamgari D. Jakobsche CE. Butler C. Miller SJ. Parr J. Crabtree RH.
  J. Organomet. Chem.  2008,  693:  1815 
  Suche in Google Scholar
• 4 Oswald CL. Peterson JA. Lam HW. Org. Lett.  2009,  11:  4504 
  CrossrefSuche in Google Scholar
• 5 Kato M. Oki H. Ogata K. Fukuzawa S. Synlett  2009,  1299 
  Thieme Connect
• 6 Kumar A. Samuelson AG. Eur. J. Org. Chem.  2011,  951 
• 7 Miura K. Tomita M. Yamada Y. Hosomi A. J. Org. Chem.  2007,  72:  787 
  CrossrefPubMedSuche in Google Scholar
• 8 Ruan ZM. Lawrence RM. Cooper CB. Tetrahedron Lett.  2006,  47:  7649 
  CrossrefSuche in Google Scholar
• 9 Finholt AE. Bond AC. Wilzbach KE. Schlesinger HI. J. Am. Chem. Soc.  1947,  69:  2692 
  CrossrefSuche in Google Scholar
• 10 Matsuoka H. Kondo K. Chin. Chem. Lett.  2010,  21:  1314 
  CrossrefSuche in Google Scholar
• 11 Sousa SCA. Fernandes AC. Adv. Synth. Catal.  2010,  352:  2218 
  CrossrefSuche in Google Scholar
• 12 Smith CA. Cross LE. Hughes K. Davis RE. Judd DB. Merritt AT. Tetrahedron Lett.  2009,  50:  4906 
  CrossrefSuche in Google Scholar
• 13 Cabrita I. Sousa SCA. Fernandes AC. Tetrahedron Lett.  2010,  51:  6132 
  CrossrefSuche in Google Scholar
• 14 Maddani MR. Moorthy SK. Prabhu KR. Tetrahedron  2010,  66:  329 
  CrossrefSuche in Google Scholar
• 15 Miura K. Yamada Y. Tomita M. Hosomi A. Synlett  2004,  1985 
  Thieme Connect
• 16 Zhou S. Junge K. Addis D. Das S. Beller M. Org. Lett.  2009,  11:  2461 
  CrossrefSuche in Google Scholar
• 17 Sugimoto O. Sugiyama M. Tanji K. Heterocycles  2010,  80:  601 
  Suche in Google Scholar
• 18 Baek JY. Lee SJ. Han BH. J. Korean Chem. Soc.  2004,  48:  220 
  CrossrefSuche in Google Scholar