Scaling and critical-like behavior in multidimensional diffusive dynamics
- 1 May 1993
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review E
- Vol. 47 (5) , 3717-3720
- https://doi.org/10.1103/physreve.47.3717
Abstract
The intermediate time dependence of the survival probability in two-dimensional diffusive dynamics is investigated on a model myoglobin-CO potential-energy surface. For small diffusion anisotropy, we derive a scaling relation for the characteristic time and exponent of the observed power-law dependence, which is verified by exact two-dimensional calculations. At higher anisotropy values, we report a critical-like jump in the anisotropy dependence of the power-law exponent. Possible experimental implications are discussed.Keywords
This publication has 19 references indexed in Scilit:
- Brownian motion in a field of force and the diffusion model of chemical reactionsPublished by Elsevier ,2004
- Relaxation dynamics of myoglobin in solutionPhysical Review Letters, 1992
- Time- and temperature dependence of large-scale conformational transitions in myoglobinChemical Physics, 1991
- Time-resolved infrared studies of molecular diffusion in myoglobinPhysical Review Letters, 1991
- Ligand binding to heme proteins: connection between dynamics and functionBiochemistry, 1991
- Diffusion theory of multidimensional activated rate processes: The role of anisotropyThe Journal of Chemical Physics, 1989
- Erratum: Transient kinetics of chemical reactions with bounded diffusion perpendicular to the reaction coordinate: Intramolecular processes with slow conformational changes [J. Chem Phys. 7 8, 6947 (1983)]The Journal of Chemical Physics, 1984
- CO binding to heme proteins: A model for barrier height distributions and slow conformational changesThe Journal of Chemical Physics, 1983
- Transient kinetics of chemical reactions with bounded diffusion perpendicular to the reaction coordinate: Intramolecular processes with slow conformational changesThe Journal of Chemical Physics, 1983
- Dynamics of ligand binding to myoglobinBiochemistry, 1975