A new kinetic approach to study the vapor-phase preparation of orthorh
ombic molybdenum trioxide (MoO3) has been established in this work. Us
ing a simple experimental setup, the vaporization and condensation of
MoO3 can be investigated with sufficient oxygen background to ensure t
he stoichiometry of the compound. The empirical condensation rate of t
he MoO3 obtained in the temperature range 642-660 degrees C is R-E = 1
.20 X 10(-3) Delta P-2.07, where Delta P is the partial pressure diffe
rence of MoO3 between the source and condensed crystals. On the basis
of the observed crystal morphology and XRD results, a more precise MoO
3 condensation kinetic model has been developed to explain the layer-b
y-layer growth of orthorhombic structure. The staged growth phenomena
call be interpreted by this mechanistic model, which correlates the co
ndensed MoO3 weight data to the experimental setup. The driving force
of the condensation growth is investigated with respect to the current
experimental conditions. For the MoO3 partial pressure ratios of 3.86
-2.97 between the source and condensed MoO3, free energy changes deter
mined for the growth are in the range -10.7 to -8.8 kJ/mol.