Heat conductivity of the DNA double helix

Savin, A. V.; Мазо, М. А.; Kikot, I. P.; Manevitch, Leonid I.; Onufriev, Alexey V.

doi:10.1103/physrevb.83.245406

Cited by 45 publications

(58 citation statements)

References 94 publications

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“…The first, which we term the "bottom-up" approach, is to fit the model to results (typically correlation functions) from a finer-grained model, which is usually an empirical all-atom model (e.g. AMBER, CHARMM), [35][36][37]63,64,[67][68][69] although fitting to energies obtained from electronic structure calculations (albeit in the absence of water) 65 has also been performed. The second "topdown" approach is to directly fit the parameters of a physically motivated potential to reproduce measured experimental properties, e.g.…”

Section: Introductionmentioning

confidence: 99%

Coarse-graining DNA for simulations of DNA nanotechnology

Doye¹,

Ouldridge²,

Louis³

et al. 2013

Phys. Chem. Chem. Phys.

193

220

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To simulate long time and length scale processes involving DNA it is necessary to use a coarse-grained description. Here we provide an overview of different approaches to such coarse graining, focussing on those at the nucleotide level that allow the self-assembly processes associated with DNA nanotechnology to be studied. OxDNA, our recently-developed coarse-grained DNA model, is particularly suited to this task, and has opened up this field to systematic study by simulations. We illustrate some of the range of DNA nanotechnology systems to which the model is being applied, as well as the insights it can provide into fundamental biophysical properties of DNA.

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Section: Introductionmentioning

confidence: 99%

Coarse-graining DNA for simulations of DNA nanotechnology

Doye¹,

Ouldridge²,

Louis³

et al. 2013

Phys. Chem. Chem. Phys.

193

220

View full text Add to dashboard Cite

show abstract

“…It is also unlikely that the strongly absorbing carbon substrate would rapidly heat the DNA structure and mediate a temperature jump. Using published values for the thermal conductivity (27), specific heat capacity (28), and density (21) of DNA, one can estimate that the DNA membrane, which connects the filaments to the carbon support, heats up on a timescale of about 100 ns after the substrate undergoes a temperature jump, far too slow to explain the oscillations of the filaments that set in promptly after the laser pulse.…”

Section: Resultsmentioning

confidence: 99%

Biomechanics of DNA structures visualized by 4D electron microscopy

Lorenz

Zewail

2013

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

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We present a technique for in situ visualization of the biomechanics of DNA structural networks using 4D electron microscopy. Vibrational oscillations of the DNA structure are excited mechanically through a short burst of substrate vibrations triggered by a laser pulse. Subsequently, the motion is probed with electron pulses to observe the impulse response of the specimen in space and time. From the frequency and amplitude of the observed oscillations, we determine the normal modes and eigenfrequencies of the structures involved. Moreover, by selective "nano-cutting" at a given point in the network, it was possible to obtain Young's modulus, and hence the stiffness, of the DNA filament at that position. This experimental approach enables nanoscale mechanics studies of macromolecules and should find applications in other domains of biological networks such as origamis.nanomechanical properties | ultrafast electron microscopy I n macroscopic engineering of structures, the nature of mechanical motions is critical for their robustness and function, as evidenced in the design of colossal structures from the Pyramids to the Eiffel Tower. Our modern-day quest for miniaturization has led to the construction of ever more sophisticated nanoscale structures and devices, defining new frontiers in materials science and nanotechnology (1). Biological nanostructures and nanomachines have also attracted considerable interest, and efforts are directed at harnessing their power for the construction of devices with novel functions (2). A prominent example is DNA nanotechnology, which exploits the fact that DNA can be programmed and made to self-assemble into complex structures and functional devices (3-5). For all of these structures and applications, the need continues for the development of suitable tools that enable the visualization of these nanoscopic systems and the control of their properties.Progress has been made in the development of techniques involving single-molecule stretching and nano-indentation (6-9) to access the intrinsic force of biological structures. Recently, ultrafast electron microscopy (UEM) has been developed to directly visualize nanomechanical motions in space and time (10, 11). The applications span a range of materials properties, including the drumming of a thin graphite membrane (12), vibrations of carbon nanotubes (13), molecular nanocrystals (14), and bimetallic nanostructures fabricated with nanoelectromechanical systems technology (15). Although it appears promising to extend these techniques to the investigation of the material properties of individual biological nanostructures, several additional challenges had to be overcome.In UEM experiments, a short laser pulse is used to excite the specimen and trigger coherent motions, which are probed with the electron pulses. However, many biological systems do not possess a suitable chromophore and may be susceptible to photodamage, as we expect for the DNA nanostructures investigated here (16). The dynamics are usually recorded in stroboscopic mode,...

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“…In particular, within the discussed two-strand ladder, thermal properties of double-or multiple-stranded molecules, such as DNA molecules or α helices in proteins, can be described. [11][12][13] …”

Section: Discussionmentioning

confidence: 99%

“…[5][6][7][8][9] Due to the structural complexity of such systems, the study of heat transport on a first-principle level becomes difficult, and thus, the development of minimal model approaches provides a very useful starting point. [10][11][12][13][14] In this context, the clarification of issues related to the validity of macroscopic phenomenological laws, e.g., Fourier's law, to describe heat propagation in nanoscale systems has attracted much attention in the field. 15,16 Thus, for harmonic systems, anomalous heat transportdiverging thermal conductivity with increasing system sizeis obtained, and thus, Fourier's law is not valid.…”

Section: Introductionmentioning

confidence: 99%

Heat transport and thermal rectification in molecular junctions: A minimal model approach

2011

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Heat conduction properties are investigated in a molecular junction modeled as a two-strand ladder with strongly asymmetric thermal transport pathways. By confining anharmonic contributions to only one of the strands, it is shown that tuning of the interstrand coupling can lead to normal heat transport and to the emergence of a well-defined temperature gradient. More interestingly, thermal rectification is obtained around a critical value of the interstrand interaction and by appropriate asymmetries induced by the coupling to the thermal baths.

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Heat conductivity of the DNA double helix

Cited by 45 publications

References 94 publications

Coarse-graining DNA for simulations of DNA nanotechnology

Coarse-graining DNA for simulations of DNA nanotechnology

Biomechanics of DNA structures visualized by 4D electron microscopy

Heat transport and thermal rectification in molecular junctions: A minimal model approach

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