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1. Intermediate and high-temperature oxidation behavior of an equiatomic TaTiCr RCCA from 800 °C to 1400 °C

   https://doi.org/10.1016/j.ijrmhm.2023.106437  

   Welch, Noah J.; Quintana, Maria J.; Kuhr, Samuel J.; Butler, Todd M.; Collins, Peter C. (January 2024, International Journal of Refractory Metals and Hard Materials)

   This study explores the oxidation behavior of a TaTiCr refractory complex concentrated alloy (RCCA) in the temperature regime of 800–1400 °C. The oxidation kinetics were found to be proportional with temperature. However, a mechanistic shift from linear oxidation kinetics at 800 °C and 1000 °C to sub-parabolic kinetics at 1200 °C and 1400 °C was observed. This was attributed to the establishment of continuous external scales of TiO2 and Cr2O3, with fairly continuous underlying complex oxide layers at the higher temperatures. While there were morphological differences in the oxide scales depending on exposure temperature, the oxide species were all similar, primarily consisting of an outer layer of TiO2, an intermediate layer of Cr2O3, and an inner layer of rutile-structured (Cr,Ta,Ti)O2. Internal nitridation was observed in all cases, with a severe degree of internal reaction at 1400 °C, reaching a depth of 750 μm. Overall, the best performance was observed at 1200 °C, where a favorable balance of kinetics and thermodynamics promoted the most continuous oxide layers, thereby enhancing oxidation resistance. 

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2. The influence of microstructure on the oxidation behavior of a TaTiCr refractory complex concentrated alloy

   https://doi.org/10.1016/j.jallcom.2024.175613  

   Welch, Noah J; Butler, Todd M; Quintana, Maria J; Collins, Peter C (October 2024, Journal of Alloys and Compounds)

   This work explores the effect of microstructure on the oxidation behavior of an equiatomic TaTiCr RCCA after 24 h of exposure at 800°C, 1000°C, 1200°C, and 1400°C. Two microstructural conditions, both containing a bcc matrix with C15 Laves precipitates, with one condition having coarser precipitates (∼10.9 µm diameter) and one condition having finer precipitates (∼2.9 µm diameter) were studied. At all oxidation temperatures except 800°C, the finer-scale (TaTiCr-F) condition experienced more rapid oxidation kinetics, higher mass gains, and thicker oxide scales and internal reaction zones. However, at 800°C, the microstructure containing coarser precipitates (TaTiCr-C) formed a thicker oxide scale. Continuous, protective Cr2O3 layers were only observed in the coarse precipitate condition and correlations between Cr2O3 layer thickness, subsequent formation of complex refractory oxides, and the initial Laves precipitate size are described. It is proposed that the formation of continuous Cr2O3 is highly dependent on the size and distribution of the Cr-rich Laves phase and only mildly dependent on phase fraction. Oxidation mechanisms for each condition are discussed relative to the initial microstructures, observed oxide species, and related alloy systems. 

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3. Examining oxidation in β-NiAl and β-NiAl+Hf alloys by stochastic cellular automata simulations

   https://doi.org/10.1038/s41529-021-00202-4  

   Roy, Indranil; Ray, Pratik K.; Balasubramanian, Ganesh (December 2021, npj Materials Degradation)

   Abstract We present results from a stochastic cellular automata (CA) model developed and employed for examining the oxidation kinetics of NiAl and NiAl+Hf alloys. The rules of the CA model are grounded in diffusion probabilities and basic principles of alloy oxidation. Using this approach, we can model the oxide scale thickness and morphology, specific mass change and oxidation kinetics as well as an approximate estimate of the stress and strains in the oxide scale. Furthermore, we also incorporate Hf in the grain boundaries and observe the “reactive element effect”, where doping with Hf results in a drastic reduction in the oxidation kinetics concomitant with the formation of thin, planar oxide scales. Interestingly, although we find that grain boundaries result in rapid oxidation of the undoped NiAl, they result in a slower-growing oxide and a planar oxide/metal interface when doped with Hf. 

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4. CMAS corrosion resistance of rare earth phosphates at high temperatures for environmental barrier coatings

   https://doi.org/10.1111/jace.20251  

   Majee, Bishnu_Pada; Bryce, Keith; Huang, Liping; Lian, Jie (November 2024, Journal of the American Ceramic Society)

   Abstract Phase stability, thermal properties, and calcium–magnesium–alumina–silicate (CMAS) resistance of LuPO₄at 1300°C, 1400°C, and 1500°C were studied to evaluate its potential as an environmental barrier coating (EBC) for SiC‐based ceramic‐matrix composites (CMCs). Its coefficient of thermal expansion (∼5.69 × 10⁻⁶°C⁻¹) is close to that of SiC‐based CMCs. At 1300°C, a dense reaction layer of Ca₈MgLu(PO₄)₇forms and inhibits CMAS penetration; however, no such layer forms at 1400°C and 1500°C, leading to CMAS infiltration along grain boundaries. Prolonged (45 and 96 hours) CMAS corrosion of LuPO₄at 1300°C showed the formation of a disilicate (Lu₂Si₂O₇) phase along with Ca₈MgLu(PO₄)₇. A multicomponent rare earth phosphate (Lu_0.2Yb_0.2Er_0.2Y_0.2Gd_0.2)PO₄shows improved CMAS resistance at 1400°C due to higher grain boundary stability and slower dissolution rate of rare earth elements into molten CMAS than single component rare earth phosphate. The mechanisms of CMAS corrosion and the kinetics of the formation of protective reaction layers in LuPO₄and (Lu_0.2Yb_0.2Er_0.2Y_0.2Gd_0.2)PO₄were elucidated. Multicomponent design is needed to increase grain boundary stability and reduce dissolution rate into molten CMAS for REPO₄‐based EBCs. 

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5. Pressure-dependent topographic evolutions of cold-sintered zinc oxide surfaces

   https://doi.org/10.1039/d1tc04651a  

   Bang, Sun Hwi; Randall, Clive A. (December 2021, Journal of Materials Chemistry C)

   By applying atomic force microscope to the flat in-plane polycrystalline microstructure, pressure-dependent topographic evolutions can be studied with respect to surface dihedral angle and groove geometry. Using a cold-sintered zinc oxide densified at 200 °C as a model system, this study demonstrates an experimental methodology for the quantification of relative grain boundary energetics in cold-sintered material systems and an associated geometric model for connecting the morphological change and underlying mechanochemical phenomenon at various uniaxial pressures ranging from 70 to 475 MPa. Depending on the applied pressure, the anisotropic grain growth, normal grain growth, and coarsening of particles are distinctively observed according to the changes in the groove geometry, suggesting that the growth kinetics can be considered as a function of pressure. 

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