Heavy-Atom Skeleton Quantization and Proton Tunneling in “Intermediate-Barrier” Hydrogen Bonds
- 21 May 2001
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 86 (21) , 4946-4949
- https://doi.org/10.1103/physrevlett.86.4946
Abstract
Quantum effects on proton transfer through barriers of several kcal/mol in hydrogen bonds are investigated theoretically in malonaldehyde. Such “intermediate-barrier” proton transfer processes play a key role in the catalytic activity of some enzymes. Tunneling is shown to be significant in this reaction even at room temperature. More importantly, the quantum nature of the heavy molecular frame atoms is found to substantially enhance proton tunneling. These findings have far-reaching implications for common modeling strategies of proton transfer in complex systems such as biomolecules.Keywords
This publication has 43 references indexed in Scilit:
- A relationship between centroid dynamics and path integral quantum transition state theoryThe Journal of Chemical Physics, 2000
- Quantum Distributions of Muonium and Hydrogen in Crystalline SiliconPhysical Review Letters, 1998
- Thermally Assisted Tunneling of the B-H Complex in SiliconPhysical Review Letters, 1997
- Thermally assisted tunneling of hydrogen in silicon: A path-integral Monte Carlo studyPhysical Review B, 1997
- Potential of mean force and reaction rates for proton transfer in acetylacetoneThe Journal of Chemical Physics, 1997
- Anharmonic Wave Functions of Proteins: Quantum Self-Consistent Field Calculations of BPTIScience, 1995
- Distinct quantum behavior of hydrogen and muonium in crystalline siliconPhysical Review Letters, 1994
- H diffusion on Ni(100): A quantum Monte Carlo simulationPhysical Review Letters, 1993
- Rigorous formulation of quantum transition state theory and its dynamical correctionsThe Journal of Chemical Physics, 1989
- Quantum simulation of hydrogen in metalsPhysical Review Letters, 1987