Cothermolysis reactions of B6H10 with the binary boranes B2H6, B4H10, B5H9,
and B5H11, have been studied by a quantitative mass-spectrometric techniqu
e to gain insight into the role of B6H10 in borane interconversion reaction
s. Except in the B6H10-B5H9 system the initial rate of consumption of B6H10
was found to be considerably more rapid than in the thermolysis of B6H10 a
lone, indicating that interactions were occurring. Detailed kinetic studies
of the B6H10-B2H6 and B6H10-B4H10 reactions showed that the rate of consum
ption of B6H10 was governed in each case by the rate-determining step in th
e decomposition of the co-reactant, the orders being 3/2 with respect to B2
H6 and I with respect to B4H10; a considerable increase in the conversion o
f B6H10 to B10H14 at the expense of polymeric solids was also observed. Add
ed hydrogen was found to have very little effect on the reaction rates and
product distributions in the cothermolysis reactions, in marked contrast to
its effect on the reactions of B2H6 and B4H10 alone. The kinetic results a
re entirely consistent with earlier suggestions, based on qualitative obser
vations, that the reactive intermediates {B3H7} and {B4H8} are scavenged by
reaction with B6H10, and suggest strongly that this borane, unlike B6H12,
plays a pivotal role in the build-up to B10H14 and other higher boranes. (C
) 2000 Elsevier Science B.V. All rights reserved.