Justin T. Fermann and Scott M. Auerbach,
``Modeling Proton Mobility in Acidic Zeolite Clusters:
III. A Sudden Approximation via Semiclassical Rate Theory,"
J. Phys. Chem. A 105, 2879-2884 (2001).
Abstract
We have developed and applied an angular sudden approximation
for modeling proton transfer is zeolites, using Miller's semiclassical
transition state theory. We have parameterized
the rate theory by performing B3LYP/6-311G(d,p) density
functional theory calculations for paths with fixed O-Al-O angle in a cluster
model of H-Y zeolite. We find that both the barrier height and barrier
curvature increase with O-Al-O angle.
We also find that the classical barrier height increases with angle
more rapidly than does the curvature, forcing the
tunneling probability to decrease strongly with angle.
The range of important angles for
proton transfer, the so-called dynamical distribution,
involves angles far from the saddle point angle at low temperatures
(i.e. large curvature paths),
and broadens significantly at higher temperatures,
encompassing the saddle point region.
The final temperature dependence of the proton jump rate within the
sudden approximation shows surprisingly good agreement with that from
conventional semiclassical
transition state theory, which is based on the minimum energy path.
We attribute this in part to a coincidence that occurs
in the temperature regime of interest, namely 200-1000 K,
a coincidence that we do not expect will occur in other systems.
Prof SM Auerbach
26 March 2001