Thermal transport across symmetric tilt grain boundaries in <i>β</i>-SiC: Effect of dopants and temperature

Goel, Nipun; Webb, Edmund B.; Rickman, J. M.; Öztekin, Alparslan; Neti, Sudhakar

doi:10.1063/1.4955431

Cited by 7 publications

(4 citation statements)

References 44 publications

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“…The thermal conductivity of polycrystals is lower than that of their corresponding single-crystals and further reduces with decreasing grain sizes due to the decreased phonon mean free paths [1,[13][14][15]. The overall thermal conductivity reduction has been observed in polycrystals of a wide variety of materials [16][17][18][19], which has been attributed to many mechanisms including the effects of grain boundaries, vacancies, impurities, and dislocations [1,[20][21][22]. Understanding the effect of grain boundaries on phonon transport is important and necessary for the engineering and design of nanomaterial thermal transport properties for many applications such as thermoelectrics [23,24], micro/nano-electromechanical devices [25], phononic devices [26], and thermal barrier coatings [17].…”

Section: Introductionmentioning

confidence: 99%

Phonon Transmission Across Silicon Grain Boundaries by Atomistic Green's Function Method

Tian

2019

Front. Phys.

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Nanostructured materials are of great interest for many applications because of their special properties. Understanding the effect of grain boundaries on phonon transport in polycrystals is important for engineering nanomaterials with desired thermal transport properties. The phonon transport properties of 3 grain boundaries in silicon are investigated by employing atomistic Green's function method. Results show that similar to electron transport, the perfect grain boundary does not significantly reduce the thermal conductance, while defective grain boundaries can dramatically reduce the thermal conductance. This work may be helpful for the understanding of the underlying thermal transport mechanism across grain boundaries and the design of grain boundaries for energy applications.

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Section: Introductionmentioning

confidence: 99%

Phonon Transmission Across Silicon Grain Boundaries by Atomistic Green's Function Method

Tian

2019

Front. Phys.

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“…In many instances, grain boundary complexion transitions can be used to enhance the processing, properties, and performance of engineering materials. In Table , we provide a summary of recent applications and examples of complexion transitions, some of which can be considered as examples of grain boundary complexion engineering (GBCE). The idea of engineering grain boundaries to enhance the bulk properties of engineering materials is not new.…”

Section: Introductionmentioning

confidence: 99%

Review of grain boundary complexion engineering: Know your boundaries

et al. 2018

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Grain boundary structure-property relationships influence bulk performance and, therefore, are an important criterion in materials design. Materials scientists can generate different grain boundary structures by changes in temperature, pressure, and chemical potential because interfaces attain their own equilibrium states, known as complexions. Complexions undergo first-order transitions by changes in thermodynamic variables, which results in discontinuous changes in properties.Grain boundary complexion engineering is introduced in this paper as a method for controlling complexion transitions to improve material performance. This International Conference on Sintering 2017 lecture describes the tools for grain boundary complexion engineering: complexion equilibrium and time-temperaturetransformation (TTT) diagrams. These tools can be implemented in processing design to tailor grain boundary properties, including grain boundary mobility.While impactful, these diagrams are often limited in scope because they are currently empirically derived. This article discusses how measurement techniques can be combined with data analytical methods to build mechanistically derived complexion equilibrium and TTT diagrams.

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“…[12][13][14][15] In general, experimental measurements are often lower than theoretically calculated values, which may be due to the existing crystal imperfections in the experimental sample. Previous researches have established that defects in crystalline materials such as point defect, [16,17] dislocation, [18] and grain boundary (GB) [19] will reduce the thermal conductivity of the SiC materials. Stacking fault (SF), as a typical GB, is widely exiting in the usual SiC materials.…”

Section: Introductionmentioning

confidence: 99%

Unveiling phonon frequency-dependent mechanism of heat transport across stacking fault in silicon carbide

et al. 2023

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Stacking faults (SFs) are often present in silicon carbide (SiC) and affect its thermal and heat-transport properties. However, it is unclear how SFs influence thermal transport. Using non-equilibrium molecular dynamics and lattice dynamics simulations, we studied phonon transport in SiC materials with a SF. Compared to perfect SiC materials, the SF can reduce thermal conductivity. This is caused by the additional interface thermal resistance (ITR) of SF, which is difficult to capture by the previous phenomenological models. By analyzing the spectral heat flux, we find that SF reduces the contribution of low-frequency (7.5-12 THz) phonons to the heat flux, which can be attributed to SF reducing the phonon lifetime and group velocity, especially in the low-frequency range. The SF hinders phonon transport and results in an effective interface thermal resistance around the SF. Our results provide insight into the microscopic mechanism of the effect of defects on heat transport and have guiding significance for the regulation of the thermal conductivity of materials.

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Thermal transport across symmetric tilt grain boundaries in β-SiC: Effect of dopants and temperature

Cited by 7 publications

References 44 publications

Phonon Transmission Across Silicon Grain Boundaries by Atomistic Green's Function Method

Phonon Transmission Across Silicon Grain Boundaries by Atomistic Green's Function Method

Review of grain boundary complexion engineering: Know your boundaries

Unveiling phonon frequency-dependent mechanism of heat transport across stacking fault in silicon carbide

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