Aluminum Hydride

Biographical Sketches

Introduction

A diethyl ether solution of three equivalents of lithium aluminum hydride with one equivalent of aluminum chloride generates a mild reducing hydride known as ‘Aluminum Hydride’ (AlH₃). [1] This reagent is very useful in synthetic organic chemistry and is easily prepared in situ and used immediately. Lithium aluminum hydride is a powerful reducing agent that can reduce several functional groups. By minimizing its reducing power, selective functional groups can be reduced. In this regard, mixed hydrides have gained a lot of interest in hydride chemistry. Adding a Lewis acid could decrease the reducing power of lithium aluminum ­hydride. AlH₃ reduces a wide variety of functional groups. [1] These include aldehydes, ketones, [2] [3] quinines, carboxylic ­acids, anhydrides, acid chlorides, esters, and lactones from which the corresponding alcohol is isolated as product. Similarly, amides, nitriles, oximes and isocyanates are reduced to amines. However, nitro compounds are inert to AlH₃. Interestingly sulfides and sulfones are unreactive but disulfides and sulfoxides can be reduced. Tosylates are not reduced.

Abstracts

(A) Reduction of α,β-unsaturated carbonyls and esters: The conversion of α,β unsaturated ketones, aldehydes, and esters into allylic alcohols can be carried out with very good selectivity using AlH3. [4] However, DIBAL is a reagent of choice for this transformation but is costly. [4a] Carboxylic acids and esters are rapidly reduced by AlH3 than LiAlH4 in presence of halides and nitro group. [5]
(B) Reduction of acetals: Cyclic acetals can be reduced to the half protected diols, which has wide applications in carbohydrate chemistry. For instance, acetals (benzylidene derivative) can be ­selectively reduced to a monobenzylated diol. [6]
(C) Reduction of amides: During the reduction of amides to amine, there is a competition between C-O and C-N bond and the cleavage depends upon the reaction conditions. This complication can be avoided with AlH3. A quantitative yield of amine is obtained within a short reaction time. Conjugated amine can be cleanly ­reduced to allylic amines, whereas LiAlH4 reduces also the con­jugated double bond. [7] Reduction of β-lactams to azetidines can be accomplished with AlH3 [8] while ring opening was observed with LiAlH4.
(D) Reduction of nitriles: The less basic AlH3 appears to be better than LiAlH4 for reducing nitriles to amines. [7]
(E) Desulfurisation: Desulfurisation of sultones is rapid and ­proceeds in good yields with AlH3, while LiAlH4 affords poor yields with long reaction times. [9]
(F) Epoxide ring opening: With most epoxides, hydride attack occurs at the least sterically hindered side to give the corresponding alcohol. [10] However due to the electrophilic nature of AlH3 compared to LiAlH4, it is possible for ring opening to occur at the more hindered side. With phenyl substituted epoxides mechanistic studies have shown that attack at benzylic carbenium ion or 1,2-hydride shift followed by hydride attack gives products with the same regiochemistry but with different stereochemistry. [7] [11] The stereoselectivity of AlH3 mediated epoxide ring opening reaction has been studied in depth. [12]
(G) SN2′ allylic rearrangements: Displacement of good leaving group to give the rearranged allylic system can be carried out with AlH3. [13] This reaction appears not to be sterically demanding as a variety of displacements are possible.
(H) Preparation of allenes: Preparation of allenes from propargylic system can also be accomplished. [13] Most systems show a preference for syn elimination. However, mesylates prefer an anti mode of elimination. This same procedure has been used to prepare fluoroallenes. [14]
(I) Miscellaneous: Though alkyl halides are usually inert to AlH3, facile reduction of cyclopropyl halides to cyclopropanes [15] and ­glycosyl fluorides to tetrahydropyrans is known. [16]

References

• 1 Finholt AE. Bond AC. Schlesinger HI. J. Am. Chem. Soc.  1947,  69:  1199 
  CrossrefGoogle Scholar
• 2a Guyon R. Villa P. Bull. Soc. Chim. Fr.  1977,  152 
  CrossrefGoogle Scholar
• 2b Martinez E. Muchowski JM. Velarde E. J. Org. Chem.  1977,  42:  1087 
  CrossrefGoogle Scholar
• 3 Corey EJ. Cane D. J. Org. Chem.  1971,  36:  3070 
  CrossrefGoogle Scholar
• 4a Wilson KE. Seidner RT. Masamune S. J. Chem. Soc., Chem. Commun.  1970,  213 
  CrossrefGoogle Scholar
• 4b Williams HJ. Tetrahedron Lett.  1975,  1271 
  CrossrefGoogle Scholar
• 4c Krishna PR. Krishnarao L. Kannan V. Tetrahedron Lett.  2004,  45:  7847 
  CrossrefGoogle Scholar
• 5 Nung MY. J. Am. Chem. Soc.  1966,  88:  1464 
  CrossrefGoogle Scholar
• 6 Sakairi N. Tokura S. Kuzuhara H. Carbohydr. Res.  1996,  291:  53 
  Google Scholar
• 7a Ashby EC. Sanders JR. Claudy P. Schwarts P. J. Am. Chem. Soc.  1973,  95:  6485 
  CrossrefGoogle Scholar
• 7b Brown HC. Nung MY. J. Am. Chem. Soc.  1966,  88:  1464 
  CrossrefGoogle Scholar
• 7c Das BK. Shibata N. Takaeuchi Y. J. Chem. Soc., Perkin Trans. 1  2002,  197 
  CrossrefGoogle Scholar
• 8 Jackson MB. Mander LN. Spotswood TM. Aust. J. Chem.  1983,  36:  779 
  Google Scholar
• 9a Wolinsky J. Marhenke RL. Eustace EJ. J. Org. Chem.  1973,  38:  1428 
  CrossrefGoogle Scholar
• 9b Smith MB. Wolinsky J. J. Org. Chem.  1981,  46:  101 
  CrossrefGoogle Scholar
• 10 Maruoka K. Saito S. Ooi T. Yamamaoto H. Synlett  1991,  255 
  Article in Thieme ConnectGoogle Scholar
• 11 Lansbury PT. Scharf DJ. Pattison VA. J. Org. Chem.  1967,  32:  1748 
  CrossrefGoogle Scholar
• 12 Elsenbaumer RL. Mosher HS. Morrison JD. Tomaszewski JE. J. Org. Chem.  1981,  46:  4034 
  CrossrefGoogle Scholar
• 13 Claesson A. Olsson LI. J. Am. Chem. Soc.  1979,  101:  7302 
  CrossrefGoogle Scholar
• 14 Castelhano A. Krantz A. J. Am. Chem. Soc.  1987,  109:  3491 
  CrossrefGoogle Scholar
• 15 Muller P. Helv. Chim. Acta  1974,  57:  407 
  Google Scholar
• 16 Nicolaou KC. Dolle RE. Chucholowski A. Randal JL. J. Chem. Soc., Chem. Commun.  1984,  1153 
  CrossrefGoogle Scholar

References

• 1 Finholt AE. Bond AC. Schlesinger HI. J. Am. Chem. Soc.  1947,  69:  1199 
  CrossrefGoogle Scholar
• 2a Guyon R. Villa P. Bull. Soc. Chim. Fr.  1977,  152 
  CrossrefGoogle Scholar
• 2b Martinez E. Muchowski JM. Velarde E. J. Org. Chem.  1977,  42:  1087 
  CrossrefGoogle Scholar
• 3 Corey EJ. Cane D. J. Org. Chem.  1971,  36:  3070 
  CrossrefGoogle Scholar
• 4a Wilson KE. Seidner RT. Masamune S. J. Chem. Soc., Chem. Commun.  1970,  213 
  CrossrefGoogle Scholar
• 4b Williams HJ. Tetrahedron Lett.  1975,  1271 
  CrossrefGoogle Scholar
• 4c Krishna PR. Krishnarao L. Kannan V. Tetrahedron Lett.  2004,  45:  7847 
  CrossrefGoogle Scholar
• 5 Nung MY. J. Am. Chem. Soc.  1966,  88:  1464 
  CrossrefGoogle Scholar
• 6 Sakairi N. Tokura S. Kuzuhara H. Carbohydr. Res.  1996,  291:  53 
  Google Scholar
• 7a Ashby EC. Sanders JR. Claudy P. Schwarts P. J. Am. Chem. Soc.  1973,  95:  6485 
  CrossrefGoogle Scholar
• 7b Brown HC. Nung MY. J. Am. Chem. Soc.  1966,  88:  1464 
  CrossrefGoogle Scholar
• 7c Das BK. Shibata N. Takaeuchi Y. J. Chem. Soc., Perkin Trans. 1  2002,  197 
  CrossrefGoogle Scholar
• 8 Jackson MB. Mander LN. Spotswood TM. Aust. J. Chem.  1983,  36:  779 
  Google Scholar
• 9a Wolinsky J. Marhenke RL. Eustace EJ. J. Org. Chem.  1973,  38:  1428 
  CrossrefGoogle Scholar
• 9b Smith MB. Wolinsky J. J. Org. Chem.  1981,  46:  101 
  CrossrefGoogle Scholar
• 10 Maruoka K. Saito S. Ooi T. Yamamaoto H. Synlett  1991,  255 
  Article in Thieme ConnectGoogle Scholar
• 11 Lansbury PT. Scharf DJ. Pattison VA. J. Org. Chem.  1967,  32:  1748 
  CrossrefGoogle Scholar
• 12 Elsenbaumer RL. Mosher HS. Morrison JD. Tomaszewski JE. J. Org. Chem.  1981,  46:  4034 
  CrossrefGoogle Scholar
• 13 Claesson A. Olsson LI. J. Am. Chem. Soc.  1979,  101:  7302 
  CrossrefGoogle Scholar
• 14 Castelhano A. Krantz A. J. Am. Chem. Soc.  1987,  109:  3491 
  CrossrefGoogle Scholar
• 15 Muller P. Helv. Chim. Acta  1974,  57:  407 
  Google Scholar
• 16 Nicolaou KC. Dolle RE. Chucholowski A. Randal JL. J. Chem. Soc., Chem. Commun.  1984,  1153 
  CrossrefGoogle Scholar