In this paper, we extend the previously described general model for charge transfer reactions, introducing specific changes to treat the hopping between energy minima of the electronic ground state (i.e., transitions between the corresponding vibrational ground states). We applied the theoretical-computational model to the charge transfer reactions in DNA molecules which still represent a challenge for a rational full understanding of their mechanism. Results show that the presented model can provide a valid, relatively simple, approach to quantitatively study such reactions shedding light on several important aspects of the reaction mechanism
A model describing charge (hole) transport in DNA has been developed. The individual charge transfer...
<p>Biological electron transfer (ET) reactions are typically described in the framework of coherent ...
We calculated electronic matrix elements for hole transfer between adjacent nucleobases in DNA. Calc...
In this paper, we extend the previously described general model for charge transfer reactions, intro...
In this work, we address the phenomenon of charge transport in DNA using a simple, but chemically sp...
In Chap. 4, Koslowski and Cramer address the phenomenon of charge transport in DNA using a simple, b...
In this work I develop and apply a theoretical method for calculating effective electronic couplings...
This article reviews our recent theoretical development toward understanding the interplay of electr...
Hole-mediated electronic couplings, reorganization energies, and electron transfer (ET) rates are ex...
The research described in this dissertation consists of two projects. First, the application and imp...
We systematically examine all the tight-binding parameters pertinent to charge transfer along DNA. T...
A formulation that readily allows quantitative comparisons with experimental chemical yields in long...
Absolute rates of hole transfer between guanine nucleobases separated by one or two A:T base pairs i...
This thesis focuses on two of the most active fields of chemical physics. One is long-range charge t...
We address the problem of charge transfer through DNA-gold junctions from a theoretical and numerica...
A model describing charge (hole) transport in DNA has been developed. The individual charge transfer...
<p>Biological electron transfer (ET) reactions are typically described in the framework of coherent ...
We calculated electronic matrix elements for hole transfer between adjacent nucleobases in DNA. Calc...
In this paper, we extend the previously described general model for charge transfer reactions, intro...
In this work, we address the phenomenon of charge transport in DNA using a simple, but chemically sp...
In Chap. 4, Koslowski and Cramer address the phenomenon of charge transport in DNA using a simple, b...
In this work I develop and apply a theoretical method for calculating effective electronic couplings...
This article reviews our recent theoretical development toward understanding the interplay of electr...
Hole-mediated electronic couplings, reorganization energies, and electron transfer (ET) rates are ex...
The research described in this dissertation consists of two projects. First, the application and imp...
We systematically examine all the tight-binding parameters pertinent to charge transfer along DNA. T...
A formulation that readily allows quantitative comparisons with experimental chemical yields in long...
Absolute rates of hole transfer between guanine nucleobases separated by one or two A:T base pairs i...
This thesis focuses on two of the most active fields of chemical physics. One is long-range charge t...
We address the problem of charge transfer through DNA-gold junctions from a theoretical and numerica...
A model describing charge (hole) transport in DNA has been developed. The individual charge transfer...
<p>Biological electron transfer (ET) reactions are typically described in the framework of coherent ...
We calculated electronic matrix elements for hole transfer between adjacent nucleobases in DNA. Calc...