Mykola Isaiev scite author profile

In this article, we demonstrate that the thermal conductivity of nanostructured porous silicon is reduced by amorphization and also that this amorphous phase in porous silicon can be created by swift (high-energy) heavy ion irradiation. Porous silicon samples with 41%-75% porosity are irradiated with 110 MeV uranium ions at six different fluences. Structural characterisation by micro-Raman spectroscopy and SEM imaging show that swift heavy ion irradiation causes the creation of an amorphous phase in porous Si but without suppressing its porous structure. We demonstrate that the amorphization of porous silicon is caused by electronic-regime interactions, which is the first time such an effect is obtained in crystalline silicon with single-ion species. Furthermore, the impact on the thermal conductivity of porous silicon is studied by micro-Raman spectroscopy and scanning thermal microscopy. The creation of an amorphous phase in porous silicon leads to a reduction of its thermal conductivity, up to a factor of 3 compared to the non-irradiated sample. Therefore, this technique could be used to enhance the thermal insulation properties of porous Si. Finally, we show that this treatment can be combined with pre-oxidation at 300 °C, which is known to lower the thermal conductivity of porous Si, in order to obtain an even greater reduction.

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Impact of screw and edge dislocations on the thermal conductivity of individual nanowires and bulk GaN: a molecular dynamics study

Termentzidis

Isaiev

Salnikova

et al. 2018

Phys. Chem. Chem. Phys.

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We report the thermal transport properties of wurtzite GaN in the presence of dislocations using molecular dynamics simulations. A variety of isolated dislocations in a nanowire configuration are analyzed and found to considerably reduce the thermal conductivity while impacting its temperature dependence in a different manner. Isolated screw dislocations reduce the thermal conductivity by a factor of two, while the influence of edge dislocations is less pronounced. The relative reduction of thermal conductivity is correlated with the strain energy of each of the five studied types of dislocations and the nature of the bonds around the dislocation core. The temperature dependence of the thermal conductivity follows a physical law described by a T variation in combination with an exponent factor that depends on the material's nature, type and the structural characteristics of the dislocation core. Furthermore, the impact of the dislocation density on the thermal conductivity of bulk GaN is examined. The variation and absolute values of the total thermal conductivity as a function of the dislocation density are similar for defected systems with both screw and edge dislocations. Nevertheless, we reveal that the thermal conductivity tensors along the parallel and perpendicular directions to the dislocation lines are different. The discrepancy of the anisotropy of the thermal conductivity grows with increasing density of dislocations and it is more pronounced for the systems with edge dislocations. Besides the fundamental insights of the presented results, these could also be used for the identification of the type of dislocations when one experimentally obtains the evolution of thermal conductivity with temperature since each type of dislocation has a different signature, or one could extract the density of dislocations with a simple measurement of thermal anisotropy.

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Efficient tuning of potential parameters for liquid–solid interactions

Isaiev

Burian

Bulavin

et al. 2015

Molecular Simulation

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Nanocrystals Growth Control during Laser Annealing of Sn:(α-Si) Composites

Neimash

Shepelyavyi

Довбешко

et al. 2016

Journal of Nanomaterials

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An efficient technique for low temperature metal-induced nanocrystalline silicon fabrication is presented. The technique is based on laser annealing of thin films of “amorphous silicon-tin” composites combined with in situ control and monitoring with Raman technique. Laser annealing was shown to provide the possibility of fine-tuning the nanocrystals size and concentration, which is important in photovoltaic and thermoelectric devices fabrication.

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Investigation of Thermal Transport Properties of Porous Silicon by Photoacoustic Technique

et al. 2015

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Thermal conductivity of partially amorphous porous silicon by photoacoustic technique

Isaiev¹,

Newby²,

Canut³

et al. 2014

Materials Letters

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Photo-induced cubic-to-hexagonal polytype transition in silicon nanowires

et al. 2019

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Raman diagnostics of photoinduced heating of silicon nanowires prepared by metal-assisted chemical etching

et al. 2015

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Mykola Isaiev

Amorphization and reduction of thermal conductivity in porous silicon by irradiation with swift heavy ions

Impact of screw and edge dislocations on the thermal conductivity of individual nanowires and bulk GaN: a molecular dynamics study

Efficient tuning of potential parameters for liquid–solid interactions

Nanocrystals Growth Control during Laser Annealing of Sn:(α-Si) Composites

Investigation of Thermal Transport Properties of Porous Silicon by Photoacoustic Technique

Thermal conductivity of partially amorphous porous silicon by photoacoustic technique

Photo-induced cubic-to-hexagonal polytype transition in silicon nanowires

Raman diagnostics of photoinduced heating of silicon nanowires prepared by metal-assisted chemical etching

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