Revisiting electronic couplings and incoherent hopping models for electron transport in crystalline C60 at ambient temperatures

Oberhofer, Harald; Blumberger, Jochen

doi:10.1039/c2cp41348e

Cited by 83 publications

(140 citation statements)

References 60 publications

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“…where h KS b is the Kohn-Sham Hamiltonian constructed from the fragment orbitals of the reduced donor and acceptor hemes (29,40) as obtained from QM/MM calculations. The final coupling matrix element is taken as the root mean square over all four possible couplings according to Eq.…”

Section: Methodsmentioning

confidence: 99%

“…Twenty-five snapshots per pair were then selected from the corresponding MD trajectories in 4-ns intervals, and the electronic coupling matrix elements were computed using the FODFT method as implemented in the CPMD program (29,40) on heme QM models interacting with the environment as implemented in the CPMD/Gromos QM/MM coupling scheme (41), and without interaction for comparison. The QM system was comprised of the porphyrin ring with all substituents saturated by a dummy hydrogen atom and the axial histidines replaced by imidazole ligands saturated with a hydrogen at the β-C atom.…”

Section: Methodsmentioning

confidence: 99%

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Electron flow in multiheme bacterial cytochromes is a balancing act between heme electronic interaction and redox potentials

Breuer

Rosso

Blumberger

2014

Proc. Natl. Acad. Sci. U.S.A.

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173

189

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The naturally widespread process of electron transfer from metal reducing bacteria to extracellular solid metal oxides entails unique biomolecular machinery optimized for long-range electron transport. To perform this function efficiently, microorganisms have adapted multiheme c-type cytochromes to arrange heme cofactors into wires that cooperatively span the cellular envelope, transmitting electrons along distances greater than 100 Å. Implications and opportunities for bionanotechnological device design are selfevident. However, at the molecular level, how these proteins shuttle electrons along their heme wires, navigating intraprotein intersections and interprotein interfaces efficiently, remains a mystery thus far inaccessible to experiment. To shed light on this critical topic, we carried out extensive quantum mechanics/molecular mechanics simulations to calculate stepwise heme-to-heme electron transfer rates in the recently crystallized outer membrane deca-heme cytochrome MtrF. By solving a master equation for electron hopping, we estimate an intrinsic, maximum possible electron flux through solvated MtrF of 10 4 -10 5 s −1 , consistent with recently measured rates for the related multiheme protein complex MtrCAB. Intriguingly, our calculations show that the rapid electron transport through MtrF is the result of a clear correlation between heme redox potential and the strength of electronic coupling along the wire: thermodynamically uphill steps occur only between electronically well-connected stacked heme pairs. This observation suggests that the protein evolved to harbor low-potential hemes without slowing down electron flow. These findings are particularly profound in light of the apparently well-conserved staggered cross-heme wire structural motif in functionally related outer membrane proteins.respiration | density functional theory

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Electron flow in multiheme bacterial cytochromes is a balancing act between heme electronic interaction and redox potentials

Breuer

Rosso

Blumberger

2014

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

173

189

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“…To evaluate the rate of transfer between an electron donor and an acceptor, three parameters are needed: the reaction free energy DG, the electronic coupling V and the reorganization energy (RE) l. V can be calculated with quantum chemistry (QC) [12], and, nowadays, also with highly accurate methods [13]. Particularly cost-efficient methods are based on the fragment molecular orbital (FMO) approaches [14][15][16][17][18] and on constrained density functional theory (DFT) [19,20]. These allow V to be calculated along nanosecond molecular dynamics (MD) trajectories [21,22].…”

Section: Introductionmentioning

confidence: 99%

A hybrid approach to simulation of electron transfer in complex molecular systems

Kubař

Elstner

2013

J. R. Soc. Interface.

130

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Electron transfer (ET) reactions in biomolecular systems represent an important class of processes at the interface of physics, chemistry and biology. The theoretical description of these reactions constitutes a huge challenge because extensive systems require a quantum-mechanical treatment and a broad range of time scales are involved. Thus, only small model systems may be investigated with the modern density functional theory techniques combined with non-adiabatic dynamics algorithms. On the other hand, model calculations based on Marcus's seminal theory describe the ET involving several assumptions that may not always be met. We review a multi-scale method that combines a non-adiabatic propagation scheme and a linear scaling quantum-chemical method with a molecular mechanics force field in such a way that an unbiased description of the dynamics of excess electron is achieved and the number of degrees of freedom is reduced effectively at the same time. ET reactions taking nanoseconds in systems with hundreds of quantum atoms can be simulated, bridging the gap between non-adiabatic ab initio simulations and model approaches such as the Marcus theory. A major recent application is hole transfer in DNA, which represents an archetypal ET reaction in a polarizable medium. Ongoing work focuses on hole transfer in proteins, peptides and organic semi-conductors.

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“…where k is the reorganization energy and H ab is the electronic coupling matrix element [14]. In the usual Marcus theory approximation the diabatic potential energy surfaces are assumed to be parabolic so that the diabatic activation energy is exactly equal to k=4 (see Fig.…”

Section: Methodsmentioning

confidence: 99%

First principles modeling of electron tunneling between defects in m-HfO2

McKenna

Blumberger

2015

Microelectronic Engineering

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a b s t r a c tDefect assisted electron transfer processes in metal-oxide materials play a key role in a diverse range of effects of relevance to microelectronic applications. However, extracting the key parameters governing such processes experimentally is a challenging problem. Here, we present a first principles based investigation into electron transfer between oxygen vacancy defects in the high-k dielectric material HfO 2 . By calculating electron transfer parameters for defects separated by up to 15 Å we show that there is a crossover from coherent to incoherent electron transfer at about 5 Å. These results can provide invaluable input into numerical simulations of electron transfer, which can be used to model and understand important effects such as trap-assisted tunneling in advanced logic and memory devices.

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Revisiting electronic couplings and incoherent hopping models for electron transport in crystalline C60 at ambient temperatures

Cited by 83 publications

References 60 publications

Electron flow in multiheme bacterial cytochromes is a balancing act between heme electronic interaction and redox potentials

Electron flow in multiheme bacterial cytochromes is a balancing act between heme electronic interaction and redox potentials

A hybrid approach to simulation of electron transfer in complex molecular systems

First principles modeling of electron tunneling between defects in m-HfO2

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