Thermal transport across nanoscale damage profile in sapphire irradiated by swift heavy ions

Abdullaev, Azat; Chauhan, Vinay; Muminov, Baurzhan; O’Connell, J.H.; Skuratov, V.A.; Khafizov, Marat; Utegulov, Zhandos

doi:10.1063/1.5126413

Cited by 19 publications

(7 citation statements)

References 59 publications

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“…When it comes to probe thermal transport properties of NP-based films, it is sufficient to use mild laser powers in contrast to the case of bulk materials, which would require much higher laser power inputs. To study heat propagation properties in nanostructured materials, a large variety of PT techniques, such as Raman spectroscopy [ 8 ], thermoreflectance [ 9 ], spectral radiometry [ 10 ] and others have been employed.…”

Section: Introductionmentioning

confidence: 99%

Photothermal Effects and Heat Conduction in Nanogranular Silicon Films

et al. 2021

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We present results on the photothermal (PT) and heat conductive properties of nanogranular silicon (Si) films synthesized by evaporation of colloidal droplets (drop-casting) of 100 ± 50 nm-sized crystalline Si nanoparticles (NP) deposited on glass substrates. Simulations of the absorbed light intensity and photo-induced temperature distribution across the Si NP films were carried out by using the Finite difference time domain (FDTD) and finite element mesh (FEM) modeling and the obtained data were compared with the local temperatures measured by micro-Raman spectroscopy and then was used for determining the heat conductivities k in the films of various thicknesses. The cubic-to-hexagonal phase transition in Si NP films caused by laser-induced heating was found to be heavily influenced by the film thickness and heat-conductive properties of glass substrate, on which the films were deposited. The k values in drop-casted Si nanogranular films were found to be in the range of lowest k of other types of nanostructurely voided Si films due to enhanced phonon scattering across inherently voided topology, weak NP-NP and NP-substrate interface bonding within nanogranular Si films.

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Section: Introductionmentioning

confidence: 99%

Photothermal Effects and Heat Conduction in Nanogranular Silicon Films

et al. 2021

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“…The simplest form for the thermal wave penetration for the TDTR geometry is given as 𝐿 KL = H𝐷/(𝜋𝑓) , where D is the diffusivity of the substrate and f is the pump modulation frequency [406,569]. TDTR has been used to study a variety of ion irradiated materials including nuclear fuel [570], nuclear fuel cladding [571], silicon carbide [572] metallic multi-layers [571], silicon [571,573], sapphire [574], and diamond [575] across orders of magnitude in thermal conductivity. MTR, also referred to as spatial domain or beam-offset thermoreflectance [576,577,578,579,580,581], has been used in the majority of studies of ion irradiated actinide oxides and their surrogates.…”

Section: Experimental Measurement Of Thermal Conductivitymentioning

confidence: 99%

Thermal Energy Transport in Oxide Nuclear Fuel

et al. 2021

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To efficiently capture the energy of the nuclear bond, advanced nuclear reactor concepts seek solid fuels that must withstand unprecedented temperature and radiation extremes. In these advanced fuels, thermal energy transport under irradiation is directly related to reactor performance as well as reactor safety. The science of thermal transport in nuclear fuel is a grand challenge due to both computational and experimental complexities. Here, we provide a comprehensive review of thermal transport research on two actinide oxides: one currently in use in commercial nuclear reactors, uranium dioxide (UO2), and one advanced fuel candidate material, thorium dioxide (ThO2). In both materials, 5Concluding Remarks .

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“…The most destructive consequences, in terms of destruction and amorphization processes, are two types of radiation damage. These are helium or hydrogen embrittlement due to processes associated with transmutation nuclear reactions under the impact of neutrons or during interaction with coolant, and the destruction of the near-surface layer due to interaction with products or fragments of nuclear fuel fission [ 16 , 17 , 18 ]. In both cases, the most vulnerable layer is the near-surface layer of structural materials, which is directly exposed to radiation.…”

Section: Introductionmentioning

confidence: 99%

“…Firstly, there is no unified theory of defect formation caused by the interaction of heavy charged particles with the structural damage material. Today there are several theoretical and experimental models attempting to describe these processes in various materials that are based on ideas about the energy exchange between the colliding particle and the material structure [ 18 , 19 , 20 , 21 , 22 ].…”

Section: Introductionmentioning

confidence: 99%

Study of Degradation Mechanisms of Strength and Thermal-Physical Properties of Nitride and Carbide Ceramics—Promising Materials for Nuclear Energy

et al. 2022

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The dependences of changes in the strength properties of nitride and carbide ceramics under high temperature irradiation with Kr15+ and Xe22+ heavy ions at irradiation doses of 1012–1015 ions/cm2 are presented in this work. The irradiation was chosen to simulate radiation damage processes that are closest to the real conditions of reactor tests in operating modes of increased temperatures. Polycrystalline ceramics based on AlN, Si3N4 nitrides, and SiC carbides were chosen as objects of research, as they have great prospects for use as a basis for structural materials for high-temperature nuclear reactors, as well as materials for nuclear waste disposal. During these studies the effect of radiation damage caused by irradiation with different fluences on the change in mechanical strength and hardness were determined, and the mechanisms causing these changes depending on the type of irradiated materials were proposed. The novelty of this study is in the results obtained determining the stability of the strength and thermophysical parameters of nitride and carbide ceramics exposed to high-temperature irradiation, which made it possible to determine the main stages and mechanisms for changing these parameters depending on the accumulated radiation damage. The relevance of this study consists not only in obtaining new data on the properties of structural materials exposed to ionizing radiation, but also in the possibility of determining the mechanisms of radiation damage in ceramics.

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Thermal transport across nanoscale damage profile in sapphire irradiated by swift heavy ions

Cited by 19 publications

References 59 publications

Photothermal Effects and Heat Conduction in Nanogranular Silicon Films

Photothermal Effects and Heat Conduction in Nanogranular Silicon Films

Thermal Energy Transport in Oxide Nuclear Fuel

Study of Degradation Mechanisms of Strength and Thermal-Physical Properties of Nitride and Carbide Ceramics—Promising Materials for Nuclear Energy

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