The effects of the reduction process, under a hydrogen flow, of a bulk WO3
tungsten oxide powder on the reactivity at 350 degrees C of 2-methylpentane
(2MP) and 4-methyl-1-pentene (4M1Pene) were investigated. The best experim
ental conditions to obtain a stable state exhibiting interesting skeletal i
somerization properties were determined. Catalyst characterization by XPS,
XRD, TPR, and surface area measurements allowed us to propose some intermed
iates phases and the corresponding nature of active sites formed during the
reduction process of the WO3 tungsten oxide. Correlations between these ca
talyst characterizations and the catalytic properties show that the WO3 pha
se is initially inactive for both alkanes and alkenes reactions. When the W
20O58 phase is formed, which corresponds to the first reduction step of WO3
, the surface becomes acidic in character, leading to the skeletal isomeriz
ation of alkenes by a monofunctional acidic mechanism. The reduction of the
W20O58 tungsten oxide occurs in two parallel ways, to WO2 and W3O, When th
is reduction is performed at moderate temperature (350 degrees C), a stable
surface composed of these two phases (WO2 and W3O) is obtained. This surfa
ce is active and very selective for the skeletal isomerization reactions of
alkanes and alkenes, This catalytic behavior has been interpreted with the
aid of two mechanisms: a bifunctional one on the WO2 phase and a monofunct
ional metallacycle one on the W3O phase. (C) 2000 Academic Press.