TY - JOUR
T1 - Theoretical Studies of Proton Transfer Reactions - Energy Barriers and the Marcus Equation
AU - Chu, Chih Hung
AU - Ho, Jia Jen
PY - 1997
Y1 - 1997
N2 - The reactants, ion-dipole complexes, transition states, and products for the proton transfer reactions HBCOH+ + OCXH → HBCO + +HOCXH optimized at the SCF/4-31G* level of theory for B, X = F, Cl, H, CH3, CH2Cl, CHCl2 and CCl3 are studied. The intrinsic barrier ΔE#BX correlates with the degree of the O-O bond contraction in the transition structure. Both intrinsic and overall barriers can be predicted with the aid of Marcus theory. Progressive degrees of chlorination of the alkyl group in B produce decreases in the barrier to proton transfer from HBCOH+ to OCXH and increases in the reverse transfer barriers. These changes can be quantitatively reproduced by the Marcus equation for all systems.
AB - The reactants, ion-dipole complexes, transition states, and products for the proton transfer reactions HBCOH+ + OCXH → HBCO + +HOCXH optimized at the SCF/4-31G* level of theory for B, X = F, Cl, H, CH3, CH2Cl, CHCl2 and CCl3 are studied. The intrinsic barrier ΔE#BX correlates with the degree of the O-O bond contraction in the transition structure. Both intrinsic and overall barriers can be predicted with the aid of Marcus theory. Progressive degrees of chlorination of the alkyl group in B produce decreases in the barrier to proton transfer from HBCOH+ to OCXH and increases in the reverse transfer barriers. These changes can be quantitatively reproduced by the Marcus equation for all systems.
KW - Ab initio
KW - Marcus theory
KW - Proton-transfer barriers
KW - Protonated formaldehyde dimer derivatives
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U2 - 10.1002/jccs.199700070
DO - 10.1002/jccs.199700070
M3 - Article
AN - SCOPUS:0346542486
SN - 0009-4536
VL - 44
SP - 455
EP - 462
JO - Journal of the Chinese Chemical Society
JF - Journal of the Chinese Chemical Society
IS - 5
ER -