to Nb(OR) 5 . The probable mode of this reaction can be represented by Eqs (2.105)

and (2.106):

Nb(NEt 2 4 C 4ROH ! Nb(OR) 4 C 4Et 2 NH "

2 . 105

Nb(OR) 4 C ROH ! Nb(OR) 5 C 2 H 2 "

2 . 106

Bradley and co-workers 332 - 334 have nicely demonstrated the importance of metal

dialkylamides as starting materials for preparation of the alkoxides of a wide range of

metals.

Reactions of M(NR 2 ) 4 (M D V, Nb, R D Et; Cr, R D Et or Pr i ;andMo,RD Me)

with 1-adamantyl alcohol have been investigated by Wilkinson and co-workers 169

and

isolated mononuclear alkoxides of these metals in the tetravalent state.

The reaction represented by Eq. (2.101) is, however, sometimes accompanied by a

change in the oxidation state of the metal. For example, Cr(NEt 2 ) 4 reacts with primary

and secondary alcohols 335 according to Eq. (2.107). Only tertiary alcohols and the

sterically demanding 3,3-dimethyl-2-butanol, 336

which are not prone to this type of

oxidation, are known 331

to give chromium( IV ) alkoxides.

2Cr(NEt 2 4 C 7R 0 R 00 CHOH ! Cr(OCHR 0 R 00 3 C R 0 R 00 CO C 8Et 2 NH " 2 . 107

Similar to the alcoholysis reaction of tetrameric aluminium isopropoxide 293 with tert -

butyl alcohol, the alcoholysis reaction of dimeric aluminium tris(dimethyl amide) 337 , 338

with tert -butyl alcohol is also slow owing to steric factors. However, the amide route

affords finally the tris product [Al OBu t 3 ], (Eq. 2.108) instead of the mixed product of

the type Al 2 OBu t 5 OPr i which was finally obtained in the reaction of [Al OPr i 3 ] 4

with an excess of Bu t OH.

Al 2 NMe 2 6 C 5Bu t OH !

5Me 2 NH

Al 2 OBu t 4 -OBu t -NMe 2

Bu t OH excess

! Al 2 OBu t 6 C Me 2 NH

2 . 108

The reactions of Bi(NMe 2 ) 3 with alcohols afford soluble and volatile alkoxides of

bismuth: 339

Bi(NMe 2 3 C 3ROH ! Bi(OR) 3 C 3Me 2 NH "

2 . 109

R D Pr i

where

(less

soluble

and

non-volatile),

CH 2 CH 2 OMe,

CH 2 CH 2 NMe 2 ,

CHMeCH 2 NMe 2 ,CMe 2 Et.

Although the utility of metal dialkylamides for the synthesis of metal alkoxides

(including tert -butoxides) had been established for many years, the progress in this

direction was rather slow up to the 1980s. Since then the alcoholysis reactions of metal

bis(trimethylsilyl) amides involving sterically hindered mono- and multi-dentate (with

more recent emphasis on specially designed donor-functionalized) alcohols to reduce

the tendency of molecular aggregation and to increase the solubility and volatility of

the resulting mono- or di-nuclear alkoxide derivatives of even more electropositive and

larger size metals, such as heavier alkaline earths and lanthanide elements, have played

a significant role in the development of exciting homometallic alkoxide systems 340 , 341

as shown by Eqs (2.110 - 2.112):