posted on 2013-08-13, 00:00authored byFrancesco Fracchia, Claudia Filippi, Claudio Amovilli
We
investigate here the performance of our recently developed linear-scaling
Jastrow-generalized-valence-bond (J-LGVB) wave functions based on
localized orbitals, for the quantum Monte Carlo (QMC) calculation
of the barrier heights and reaction energies of five prototypical
chemical reactions. Using the geometrical parameters from the Minnesota
database collection, we consider three hydrogen-exchanges, one heavy-atom
exchange, and one association reaction and compare our results with
the best available experimental and theoretical data. For the three
hydrogen-exchange reactions, we find that the J-LGVB wave functions
yield excellent QMC results, with average deviations from the reference
values below 0.5 kcal/mol. For the heavy-atom exchange and association
reactions, additional resonance structures are important, and we therefore
extend our original formulation to include multiple coupling schemes
characterized by different sets of localized orbitals. We denote these
wave functions as J-MC-LGVB, where MC indicates the multiconfiguration
generalization, and show that such a form leads to very accurate barrier
heights and reaction energies also for the last two reactions. We
can therefore conclude that the J-LGVB theory for constructing QMC
wave functions, with its multiconfiguration generalization, is valid
for the study of large portions of ground-state potential energy surfaces
including, in particular, the region of transition states.