Charge Transfer in Deoxyribonucleic Acid (DNA): Static Disorder, Dynamic Fluctuations and Complex Kinetic.

The fact that loosely bonded DNA bases could tolerate large structural fluctuations, form a dissipative environment for a charge traveling through the DNA. Nonlinear stochastic nature of structural fluctuations facilitates rich charge dynamics in DNA. We study the complex charge dynamics by solving...

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Main Author: Edirisinghe Pathirannehelage, Neranjan S
Format: Others
Published: ScholarWorks @ Georgia State University 2011
Subjects:
Online Access:http://scholarworks.gsu.edu/phy_astr_diss/45
http://scholarworks.gsu.edu/cgi/viewcontent.cgi?article=1044&context=phy_astr_diss
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spelling ndltd-GEORGIA-oai-scholarworks.gsu.edu-phy_astr_diss-10442015-07-03T03:41:53Z Charge Transfer in Deoxyribonucleic Acid (DNA): Static Disorder, Dynamic Fluctuations and Complex Kinetic. Edirisinghe Pathirannehelage, Neranjan S The fact that loosely bonded DNA bases could tolerate large structural fluctuations, form a dissipative environment for a charge traveling through the DNA. Nonlinear stochastic nature of structural fluctuations facilitates rich charge dynamics in DNA. We study the complex charge dynamics by solving a nonlinear, stochastic, coupled system of differential equations. Charge transfer between donor and acceptor in DNA occurs via different mechanisms depending on the distance between donor and acceptor. It changes from tunneling regime to a polaron assisted hopping regime depending on the donor-acceptor separation. Also we found that charge transport strongly depends on the feasibility of polaron formation. Hence it has complex dependence on temperature and charge-vibrations coupling strength. Mismatched base pairs, such as different conformations of the G・A mispair, cause only minor structural changes in the host DNA molecule, thereby making mispair recognition an arduous task. Electron transport in DNA that depends strongly on the hopping transfer integrals between the nearest base pairs, which in turn are affected by the presence of a mispair, might be an attractive approach in this regard. I report here on our investigations, via the I –V characteristics, of the effect of a mispair on the electrical properties of homogeneous and generic DNA molecules. The I –V characteristics of DNA were studied numerically within the double-stranded tight-binding model. The parameters of the tight-binding model, such as the transfer integrals and on-site energies, are determined from first-principles calculations. The changes in electrical current through the DNA chain due to the presence of a mispair depend on the conformation of the G・A mispair and are appreciable for DNA consisting of up to 90 base pairs. For homogeneous DNA sequences the current through DNA is suppressed and the strongest suppression is realized for the G(anti)・A(syn) conformation of the G・A mispair. For inhomogeneous (generic) DNA molecules, the mispair result can be either suppression or an enhancement of the current, depending on the type of mispairs and actual DNA sequence. 2011-01-07T08:00:00Z text application/pdf http://scholarworks.gsu.edu/phy_astr_diss/45 http://scholarworks.gsu.edu/cgi/viewcontent.cgi?article=1044&context=phy_astr_diss Physics and Astronomy Dissertations ScholarWorks @ Georgia State University Deoxyribonucleic acid Non equilibrium Greens’ function Model hamiltonian Stochastic differential equations Polaron Parallel and distributed computing
collection NDLTD
format Others
sources NDLTD
topic Deoxyribonucleic acid
Non equilibrium Greens’ function
Model hamiltonian
Stochastic differential equations
Polaron
Parallel and distributed computing
spellingShingle Deoxyribonucleic acid
Non equilibrium Greens’ function
Model hamiltonian
Stochastic differential equations
Polaron
Parallel and distributed computing
Edirisinghe Pathirannehelage, Neranjan S
Charge Transfer in Deoxyribonucleic Acid (DNA): Static Disorder, Dynamic Fluctuations and Complex Kinetic.
description The fact that loosely bonded DNA bases could tolerate large structural fluctuations, form a dissipative environment for a charge traveling through the DNA. Nonlinear stochastic nature of structural fluctuations facilitates rich charge dynamics in DNA. We study the complex charge dynamics by solving a nonlinear, stochastic, coupled system of differential equations. Charge transfer between donor and acceptor in DNA occurs via different mechanisms depending on the distance between donor and acceptor. It changes from tunneling regime to a polaron assisted hopping regime depending on the donor-acceptor separation. Also we found that charge transport strongly depends on the feasibility of polaron formation. Hence it has complex dependence on temperature and charge-vibrations coupling strength. Mismatched base pairs, such as different conformations of the G・A mispair, cause only minor structural changes in the host DNA molecule, thereby making mispair recognition an arduous task. Electron transport in DNA that depends strongly on the hopping transfer integrals between the nearest base pairs, which in turn are affected by the presence of a mispair, might be an attractive approach in this regard. I report here on our investigations, via the I –V characteristics, of the effect of a mispair on the electrical properties of homogeneous and generic DNA molecules. The I –V characteristics of DNA were studied numerically within the double-stranded tight-binding model. The parameters of the tight-binding model, such as the transfer integrals and on-site energies, are determined from first-principles calculations. The changes in electrical current through the DNA chain due to the presence of a mispair depend on the conformation of the G・A mispair and are appreciable for DNA consisting of up to 90 base pairs. For homogeneous DNA sequences the current through DNA is suppressed and the strongest suppression is realized for the G(anti)・A(syn) conformation of the G・A mispair. For inhomogeneous (generic) DNA molecules, the mispair result can be either suppression or an enhancement of the current, depending on the type of mispairs and actual DNA sequence.
author Edirisinghe Pathirannehelage, Neranjan S
author_facet Edirisinghe Pathirannehelage, Neranjan S
author_sort Edirisinghe Pathirannehelage, Neranjan S
title Charge Transfer in Deoxyribonucleic Acid (DNA): Static Disorder, Dynamic Fluctuations and Complex Kinetic.
title_short Charge Transfer in Deoxyribonucleic Acid (DNA): Static Disorder, Dynamic Fluctuations and Complex Kinetic.
title_full Charge Transfer in Deoxyribonucleic Acid (DNA): Static Disorder, Dynamic Fluctuations and Complex Kinetic.
title_fullStr Charge Transfer in Deoxyribonucleic Acid (DNA): Static Disorder, Dynamic Fluctuations and Complex Kinetic.
title_full_unstemmed Charge Transfer in Deoxyribonucleic Acid (DNA): Static Disorder, Dynamic Fluctuations and Complex Kinetic.
title_sort charge transfer in deoxyribonucleic acid (dna): static disorder, dynamic fluctuations and complex kinetic.
publisher ScholarWorks @ Georgia State University
publishDate 2011
url http://scholarworks.gsu.edu/phy_astr_diss/45
http://scholarworks.gsu.edu/cgi/viewcontent.cgi?article=1044&context=phy_astr_diss
work_keys_str_mv AT edirisinghepathirannehelageneranjans chargetransferindeoxyribonucleicaciddnastaticdisorderdynamicfluctuationsandcomplexkinetic
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