Microstructure and high temperature properties of Mo(Si,Al)2 - The effect of particle strengthening and alloying
Doktorsavhandling, 2024
Mo(Si,Al)2 is a ceramic material commonly used for heating elements in various high temperature furnaces and is being considered for large-scale industrial-scale applications. While its oxidation properties have been extensively studied, its mechanical properties, which are crucial when increasing the size of the heating elements, have received limited attention. In this thesis, the high temperature deformation behaviour of Mo(Si,Al)2-based materials, and potential routes for their improvement, have been investigated.
This work has shown that diffusion-driven grain boundary sliding is the main deformation mechanism in polycrystalline Mo(Si,Al)2, particularly in fine-grained materials. In coarse-grained materials, the slip of dislocations also contributes to deformation. Moreover, coarse-grained Mo(Si,Al)2 relaxes through the formation of low-angle grain boundaries and dynamic recrystallization. The addition of Al2O3 particles, to achieve particle strengthening, results in a competition between a negative effect from grain refinement at low fractions (up to 15 wt.%), and a positive effect from inhibition of grain boundary sliding at higher fractions.
Also alloying with W, Nb, Ta, and V has been studied, among which W was the most promising alternative. The solid solubility of W in Mo(Si,Al)2 was high, and it also led to a slight improvement in high temperature strength. The solubility of the alloying elements Nb, Ta, and V was found to be low in Mo(Si,Al)2. Instead, these elements were enriched in secondary phases. Additionally, Y alloying has been explored to investigate its effect on oxidation behaviour. However, the oxide adhesion was adversely affected.
microstructure
particle strengthening
Mo(Si,Al)2
oxidation
alloying
high temperature mechanical properties
Författare
Aina Edgren
Chalmers, Fysik, Mikrostrukturfysik
Alloying of C40-structured Mo(Si,Al)<inf>2</inf> with Nb, Ta and V
Materials Letters,;Vol. 353(2023)
Artikel i vetenskaplig tidskrift
High temperature compression of Mo(Si,Al)2-Al2O3 composites
Materials Science & Engineering A: Structural Materials: Properties, Microstructure and Processing,;Vol. 865(2023)
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Influence of Yttrium Doping on the Oxidation of Mo(Si,Al)<inf>2</inf> in Air at 1500 °C
Oxidation of Metals,;Vol. In Press(2022)
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High temperature deformation of polycrystalline C40 Mo(Si,Al)<inf>2</inf>
Materials Science & Engineering A: Structural Materials: Properties, Microstructure and Processing,;Vol. 849(2022)
Artikel i vetenskaplig tidskrift
Aina Edgren, Erik Ström, Magnus Hörnqvist Colliander. Competing high-temperature deformation mechanisms in Mo(Si,Al)2-Al2O3 composites
This doctoral thesis investigates Mo(Si,Al)2, a material often used for small resistive heating elements. Because of its low density, high resistivity, and exceptional oxidation resistance, Mo(Si,Al)2 shows potential for being used as heating elements also within the steel industry. However, to heat large furnaces used for different types of processes, the size of the elements needs to increase. This could be problematic because the mechanical properties of Mo(Si,Al)2 are relatively poor, and the elements may deform by their own weight. In this thesis, different methods to improve the strength of the material are investigated.
With the aid of advanced electron microscopy and X-ray diffraction, Mo(Si,Al)2-based materials are studied at the micron level, uncovering previously unknown deformation mechanisms. These results could be used in the transition to a more sustainable steel industry.
Ämneskategorier
Materialteknik
Keramteknik
Fysik
Materialkemi
Metallurgi och metalliska material
Infrastruktur
Chalmers materialanalyslaboratorium
Styrkeområden
Materialvetenskap
ISBN
978-91-8103-013-6
Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 5471
Utgivare
Chalmers
PJ-salen, Origohuset, Fysik, Fysikgränd 3
Opponent: Manja Krüger, Institute of Materials and Joining Technology, Otto von Guericke University, Magdeburg, Tyskland