Combined EBSD and Computer-Assisted Quantitative Analysis of the Impact of Spark Plasma Sintering Parameters on the Structure of Porous Materials

Nosewicz, Szymon; Jurczak, G.; Chromiński, Witold; Rojek, Jerzy; Kaszyca, Kamil; Chmielewski, Marcin

doi:10.1007/s11661-022-06821-z

Cited by 7 publications

(1 citation statement)

References 65 publications

(91 reference statements)

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“…The more advanced approach is presented in work [ 3 ], where the authors compare grain growth as a function of temperature in transparent ceramics. Work [ 4 ] presents the comparison of simulated and experimental data of SPS samples and applies the temperature-gradient issue to the created model. The cited works show the increase in complexity of research connected with modeling and justify the necessity of the SPS system functionality expansion.…”

Section: Introductionmentioning

confidence: 99%

Using the Spark Plasma Sintering System for Fabrication of Advanced Semiconductor Materials

Kaszyca,

Chmielewski,

Bucholc

et al. 2024

Materials

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The interest in the Spark Plasma Sintering (SPS) technique has continuously increased over the last few years. This article shows the possibility of the development of an SPS device used for material processing and synthesis in both scientific and industrial applications and aims to present manufacturing methods and the versatility of an SPS device, presenting examples of processing Arc-Melted- (half-Heusler, cobalt triantimonide) and Self-propagating High-temperature Synthesis (SHS)-synthesized semiconductor (bismuth telluride) materials. The SPS system functionality development is presented, the purpose of which was to broaden the knowledge of the nature of SPS processes. This approach enabled the precise design of material sintering processes and also contributed to increasing the repeatability and accuracy of sintering conditions.

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Section: Introductionmentioning

confidence: 99%

Using the Spark Plasma Sintering System for Fabrication of Advanced Semiconductor Materials

Kaszyca,

Chmielewski,

Bucholc

et al. 2024

Materials

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Discrete element model for effective electrical conductivity of spark plasma sintered porous materials

Nisar,

Rojek,

Nosewicz

et al. 2024

Comp. Part. Mech.

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This paper aims to analyse electrical conduction in partially sintered porous materials using an original resistor network model within discrete element framework. The model is based on sintering geometry, where two particles are connected via neck. Particle-to-particle conductance depends on neck size in sintered materials. Therefore, accurate evaluation of neck size is essential to determine conductance. The neck size was determined using volume preservation criterion. Additionally, grain boundary correction factor was introduced to compensate for any non-physical overlaps between particles, particularly at higher densification. Furthermore, grain boundary resistance was added to account for the porosity within necks. For numerical analysis, the DEM sample was generated using real particle size distribution, ensuring a heterogeneous and realistic microstructure characterized by a maximum-to-minimum particle diameter ratio of 15. The DEM sample was subjected to hot press simulation to obtain geometries with different porosity levels. These representative geometries were used to simulate current flow and determine effective electrical conductivity as a function of porosity. The discrete element model (DEM) was validated using experimentally measured electrical conductivities of porous NiAl samples manufactured using spark plasma sintering (SPS). The numerical results were in close agreement with the experimental results, hence proving the accuracy of the model. The model can be used for microscopic analysis and can also be coupled with sintering models to evaluate effective properties during the sintering process.

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Consolidation of mechanically alloyed powders

Nasimul Alam,

Arka,

Nityananda

et al. 2024

Mechanical Alloying of Ferrous and Non-Ferrous Alloys

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Combined EBSD and Computer-Assisted Quantitative Analysis of the Impact of Spark Plasma Sintering Parameters on the Structure of Porous Materials

Cited by 7 publications

References 65 publications

Using the Spark Plasma Sintering System for Fabrication of Advanced Semiconductor Materials

Using the Spark Plasma Sintering System for Fabrication of Advanced Semiconductor Materials

Discrete element model for effective electrical conductivity of spark plasma sintered porous materials

Consolidation of mechanically alloyed powders

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