Impact of grain boundary characteristics on thermal transport in polycrystalline graphene: Analytical results

Krasavin, S. E.; Osipov, V. A.

doi:10.1063/1.5082151

Cited by 5 publications

(5 citation statements)

References 32 publications

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“…In fact, the GBs in the actual structure are often complex and irregular, which violates the ideal constancy of misorientation and leads to a significant decrease in κ. 100 Considering BC-G, the effect of the misorientation angle to κ is more obvious, as shown in Fig. 3(c).…”

Section: A Defects and Disordersmentioning

confidence: 91%

Efficient modulation of thermal transport in two-dimensional materials for thermal management in device applications

et al. 2023

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Section: A Defects and Disordersmentioning

confidence: 91%

Efficient modulation of thermal transport in two-dimensional materials for thermal management in device applications

et al. 2023

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“…Earlier, in the study of heat transport in graphene (see Ref. 23 ), we have shown the possibility, within the framework of our approach, of taking into account any number of PDDs (including those with different ω ) inside the GB wall. Which is important in calculations, one can consider many built-in PDDs as one with a total arm length.…”

Section: Modelmentioning

confidence: 96%

“…It is well known that the effect of strain field can be described within the deformation potential theory 26 . In our approach, the total strain field caused by the GB at any point of graphene sheet is determined through a sum of strain fields from all 5-7 pairs 23 . In this way, for a GB oriented in the x-direction, the deformation potential V ǫ (r) takes the form where TrE ij (r) is the trace of the strain tensor, G is the deformation potential constant, is the modulus of the Frank vector which, for the chosen geometry, is directed along the z axis, p is the number of 5-7 pairs in the GB, ζ is the is Poisson's ratio, ( x ni , y ni ) are coordinates of i-th disclination in n-th dipole.…”

Section: Modelmentioning

confidence: 99%

“…This allowed us to describe the features of electron and phonon scattering in polycrystalline materials due to long-range strain fields 22 . Recently, we presented a general scheme that allows us to calculate strain fields in graphene caused by GB of any size and shape as a sum of strains of 5-7 disclination dipoles 23 . This approach has been applied to the analysis of heat transport in polycrystalline graphene 23 and allows us to consider any possible configurations of GBs including closed defects like the Stone-Walles 24 .…”

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confidence: 99%

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Electrical resistivity of polycrystalline graphene: effect of grain-boundary-induced strain fields

Krasavin

Osipov

2022

Sci Rep

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We have revealed the decisive role of grain-boundary-induced strain fields in electron scattering in polycrystalline graphene. To this end, we have formulated the model based on Boltzmann transport theory which properly takes into account the microscopic structure of grain boundaries (GB) as a repeated sequence of heptagon–pentagon pairs. We show that at naturally low GB charges the strain field scattering dominates and leads to physically reasonable and, what is important, experimentally observable values of the electrical resistivity. It ranges from 0.1 to 10 k$$\Omega$$ Ω $$\upmu m$$ μ m for different types of symmetric GBs with a size of 1 $$\upmu$$ μ m and has a strong dependence on misorientation angle. For low-angle highly charged GBs, two scattering mechanisms may compete. The resistivity increases markedly with decreasing GB size and reaches values of 60 k$$\Omega$$ Ω $$\upmu$$ μ m and more. It is also very sensitive to the presence of irregularities modeled by embedding of partial disclination dipoles. With significant distortion, we found an increase in resistance by more than an order of magnitude, which is directly related to the destruction of diffraction on the GB. Our findings may be of interest both in the interpretation of experimental data and in the design of electronic devices based on poly- and nanocrystalline graphene.

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“…It is well known that the effect of strain field can be described within the deformation potential theory [26]. In our approach, the total strain field caused by the GB at any point of graphene sheet is determined through a sum of strain fields from all 5-7 pairs [23]. In this way, for a GB oriented in the x-direction, the deformation potential V (r) takes the form…”

Section: Modelmentioning

confidence: 99%

Electrical Resistivity of Polycrystalline Graphene: Effect of Grain-Boundary-Induced Strain Fields

Krasavin¹,

Osipov²

2022

Preprint

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We have revealed the decisive role of grain-boundary-induced strain fields in electron scattering in polycrystalline graphene. To this end, we have formulated the model based on Boltzmann transport theory which properly takes into account the microscopic structure of grain boundaries (GB) as a repeated sequence of heptagon-pentagon pairs. The effect of strain field is described within the deformation potential theory. For comparison, we consider the scattering due to electrostatic potential of charged grain boundary. We show that at naturally low GB charges the deformation potential scattering dominates and leads to physically reasonable and, what is important, experimentally observable values of the electrical resistivity. It ranges from 0.1 to 10 kΩµm for different types of GBs with a size of 1 µm and has a strong dependence on misorientation angle. For low-angle highly charged GBs, two scattering mechanisms may compete. The resistivity increases markedly with decreasing GB size and reaches values of 60 kΩµm and more. It is also very sensitive to the presence of irregularities modeled by embedding of partial disclination dipoles. With significant distortion, we found an increase in resistance by more than an order of magnitude, which is directly related to the destruction of diffraction on the GB. Our findings may be of interest both in the interpretation of experimental data and in the design of electronic devices based on poly-and nanocrystalline graphene.

show abstract

Impact of grain boundary characteristics on thermal transport in polycrystalline graphene: Analytical results

Cited by 5 publications

References 32 publications

Efficient modulation of thermal transport in two-dimensional materials for thermal management in device applications

Efficient modulation of thermal transport in two-dimensional materials for thermal management in device applications

Electrical resistivity of polycrystalline graphene: effect of grain-boundary-induced strain fields

Electrical Resistivity of Polycrystalline Graphene: Effect of Grain-Boundary-Induced Strain Fields

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