1. Charge transfer through the nucleosome: a theoretical approach
- Author
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Thorsten Koslowski, Tobias Cramer, Sebastian Krapf, Cramer, Tobia, Krapf, Sebastian, and Koslowski, Thorsten
- Subjects
Work (thermodynamics) ,Superhelix ,Chemistry ,Stereochemistry ,Model Hamiltonian ,General Physics and Astronomy ,Charge Trapping Dynamics ,Charge (physics) ,DNA ,Electronic structure ,Hopping Transport ,Marcus theory ,Electron transfer ,Chemical physics ,Potential energy surface ,Charge Transfer ,A-DNA ,Physical and Theoretical Chemistry - Abstract
In this work, we approach the problem of charge transfer in deoxyribonucleic acid (DNA) from a theoretical and numerical perspective. We focus on a DNA geometry characteristic of the eukaryotic genome and study transport along a superhelix that contains 292 nucleobases. The electronic structure is described within the Su-Schrieffer-Heeger model in an atomistic parameterization, which has been extended by a nonretarded reaction field to take dielectric polarization effects into account. The emerging potential energy surface is analyzed using the Marcus theory of electron transfer. The computed reaction coefficients are compared to their counterparts originating from idealized geometries and to experimental findings. This comparison and the palindromic nature of the DNA sequence used here permit the assessment of fluctuations in the local orientation of the bases and their impact upon transport properties.
- Published
- 2004
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