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TheoreticalBackground
2.4 DynamicsofExcessCharge inDNA
Inspiteofexcessiveresearch in thefieldofchargemigrationthroughbiomolecules,
especially through DNA, no unified explanation of the microscopic mechanisms
has been found until now. Two basic concepts regarding the dynamics of charge
have been established, the charge transport and the charge transfer. The former,
is the physicist’s approachwhichdescribes the ability ofDNA to support electric
current. The latter is the chemical (physics) approach of charge transfer inDNA
involvingmulti-stephoppingprocesses.
Eitherway, thecomputationalmodelusedforchargetransport/transferdescription
in DNA has to fulfill several requirements. Firstly, the computational efficiency
has to be high enough to take dynamic effects on the nanosecond timescale into
account. Secondly, ithas tobeable toreproducetheresultsofhigher-levelmethods
inaqualitativeway.
Thefirst conceptused in thisworkwillbe thecalculationofcharge transportprop-
ertieswithQMmethodsonstructuralensemblesoriginatingfromMDsimulations.
In this case, themolecular structure is simulatedwithout the chargeactuallybeing
in the system. Thus, the structure and dynamics of the molecule are unaffected
by the charge in the system. TheCTproperties are calculated on these “neutral”
structures over several thousand snapshots. This provides an insight into the dy-
namics ofCT efficiency. This previously developedmulti-scale framework for the
dynamic calculation of charge transport properties [45] has already been applied
successfully to fullyhydratedDNAspecies ina free state.[44,69,70]
In the secondpart,mechanismsof charge transferwill be introduced. Theclassical
description of charge transfer inmolecular systems in apolarizablemediumgoes
back to the theory ofMarcus [71]. First, the general concept and the neededCT
parameterswill be introduced. Then, the computational approaches used in this
work will be presented. The computation of charge transfer here is based on a
direct combination of force field andquantummethods. TheMMenvironment is
influenced by the charge residing on the nucleobases and reacts accordingly. To
make such an approach computationally efficient, several assumptions have to be
made, whichwill be described in detail. The basics of thismulti-scale approach
have recently beendescribedbyT.Kubarˇ andM.Elstner[72, 73] andwill be sum-
marized in this thesis.
24
Charge Transport in DNA
Insights from Simulations
- Titel
- Charge Transport in DNA
- Untertitel
- Insights from Simulations
- Autor
- Mario Wolter
- Verlag
- KIT Scientific Publishing
- Datum
- 2013
- Sprache
- englisch
- Lizenz
- CC BY-SA 3.0
- ISBN
- 978-3-7315-0082-7
- Abmessungen
- 17.0 x 24.0 cm
- Seiten
- 156
- Schlagwörter
- Charge Transport, Charge Transfer, DNA, Molecular Dynamics, Quantum Mechanics
- Kategorien
- Naturwissenschaften Chemie
Inhaltsverzeichnis
- Zusammenfassung 1
- Summary 3
- 1 Introduction 5
- 2 TheoreticalBackground 11
- 3 SimulationSetup 39
- 4 DNAUnderExperimentalConditions 49
- 5 ChargeTransport inStretchedDNA 69
- 6 ChargeTransport inMicrohydratedDNA 79
- 7 AParametrizedModel toSimulateCT inDNA 89
- 8 Conclusion 105
- Appendix 111
- A DNAUnderExperimentalConditions 111
- B CTinMicrohydratedDNA 117
- List ofPublications 137