Geodesic
Charge motion along polynucleotide chains in a constant electric field depends on the charge coupling constant with chain displacements
Matematičeskaâ biologiâ i bioinformatika, Tome 17 (2022) no. 3, pp. t1-t13

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Various regimes of a charge motion along a chain in a constant electric field are investigated. This motion is simulated on the basis of the Holstein model. Earlier studies demonstrate a possibility of a uniform motion of a charge in a constant electric field over very long distances. For small values of the electric field intensity a Holstein polaron can move at a constant velocity. As the electric field intensity increases, a charge motion acquires oscillatorily character, performing Bloch oscillations. Since the charge motion depends on the whole set of the system parameters the character of the motion depends not only on the value of the electric field intensity. Therefore, the electric field intensity for which the uniform motion takes place differs for chains with different parameters. The character of the charge motion and distribution is considered in chains with different values of the constant of coupling between the charge and the displacements of the chain. We showed that the values of the electric field intensity for which the regime of a charge motion changes are different in chains with different values of the coupling constant. We also demonstrated that for one and the same value of the electric field intensity, in chains with different values of the coupling constant either a uniform motion or an oscillatory motion, or a stationary polaron can be observed. 
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     title = {Charge motion along polynucleotide chains in a constant electric field depends on the charge coupling constant with chain displacements},
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A. N. Korshounova; V. D. Lakhno. Charge motion along polynucleotide chains in a constant electric field depends on the charge coupling constant with chain displacements. Matematičeskaâ biologiâ i bioinformatika, Tome 17 (2022) no. 3, pp. t1-t13. http://geodesic.mathdoc.fr/item/MBB_2022_17_3_a0/

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