Ab initio electronic structure calculations and variational transition state theory are used to calculate reaction
energetics and rate constants for the gas-phase reactions of OH- with CH(4
-
n
)Cl
n
for n = 1−4. Two reaction
pathways are considered, second-order (bimolecular) nucleophilic substitution (SN2), and proton transfer.
Benchmark electronic structure calculations using CCSD(T) and basis sets as large as aug-cc-pVQZ are
performed to obtain highly accurate estimates of the enthalpies of reaction. These results are extrapolated to
the complete basis set limit for comparison with experiment and to establish the level of theory needed to
provide energies that are accurate to better than a few kJ/mol. Energies of critical geometries (reactant
complexes, saddle points, and product complexes) are computed for all systems. For the SN2 reaction, the
potential energy and its first and second derivatives along minimum energy paths are computed and used
directly in variational transition state theory (VTST) calculations of the rate constants. These calculations
indicate that for n = 1−3 the region of the potential in the asymptotic reactant channel controls the reaction
rate constants and that the loose-transition-state methods implemented in variflex provide the best estimates
of the reaction rate constants. The reaction with n = 4 has a dynamical bottleneck that lies near the saddle
point and is best treated using the VTST methods implemented in polyrate.
Photochemical properties of a series of bifunctional monosubstituted derivatives of cymantrene containing a C-, N-, or O-bound π-allyl group, along with n-donating carbamate, amide, or pyridine fragments were investigated. The results obtained demonstrate that the nature and thermodynamic stability of the cyclopentadienylmanganese dicarbonyl chelates derived from bifunctional monosubstituted cymantrene derivatives depend substantially on both the nature of the functional groups and on their position in the substituent at the Cp ring. Thus, for the six-membered chelates, the thermodynamic stability increases in the series carbamates < amides < pyridines < olefins. Some of the dicarbonyl chelates studied form reversible photochromic systems due to linkage isomerization between different donating groups of the bifunctional substituent and the manganese atom with a wide range of times of thermal isomerization.
This study utilizes ab initio calculations to investigate the reaction of high-temperature solid-state catalytic
isotope exchange (HSCIE) between amino acids and spillover tritium. The Hartree−Fock approximation and
second-order Møller−Plesset perturbation theory in conjunction with 6-31G* and aug-cc-pVDZ basis sets
were used to calculate potential energy surfaces for the interactions between CH4, alanine, hydroxyproline,
and the H3O+ ion. Ab initio calculations were used to estimate the activation energies and structures of the
transition states of these reactions. The hydrogen exchange reaction occurs by a synchronous mechanism,
with a transition state that is characterized by pentacoordinated carbon. The proposed one-center mechanism
is in good agreement with observed retention of configuration of the asymmetric carbon atoms in the HSCIE
reaction with spillover tritium in experiments. The regioselectivity and stereoselectivity of hydrogen isotope
exchange in amino acids with spillover tritium can be predicted on the basis of ab initio calculations of
interaction of this compound with a model acidic center, taking the H3O+ ion as an example.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.