References
- Oskarsson H. Material challenges in industrial gas turbines. J Iron And Steel Res Int. 2007;14(5):11–14.
- Pollock TM, Tin S. Nickel-based superalloys for advanced turbine engines: chemistry, microstructure, and properties. J Propul Power. 2006;22(2):361–374.
- Goebel JA, Pettit FS, Goward GW. Mechanisms for the hot corrosion of ni-base alloys. Metall Trans. 1973;4(1):261–278.
- Potter A, Sumner J, Simms NJ. The role of superalloy precipitates on the early stages of oxidation and type II hot corrosion. Mater High Temp. 2018;3409(1–3):236–242.
- Potter A, Sumner J, Simms NJ, et al., “Hot corrosion in the next generation of industrial gas turbines,” Eurocorr 2014; 8-12/9/2014; Piza, 2014.
- Pettit F. Hot corrosion of metals and alloys. Oxid Met. 2011;76(1–2):1–21.
- Birks N, Meier GH, Pettit FS. Introduction to the high-temperature oxidation of metals, Vol. 2. Cambridge: Cambridge University Press; 2006. 10.1017/CBO9781139163903
- Potter A, Sumner J, Simms NJ. The effects of water vapour on the hot corrosion of gas turbine blade materials at 700 °C. Mater High Temp. 2022;39(3):231–238.
- Turazi A, de Oliveira CAS, Bohórquez CEN, et al. Study of GTD-111 superalloy microstructural evolution during high-temperature aging and after rejuvenation treatments. Metallogr Microstruct Anal. 2015;4(1):3–12.
- Biss V. Phase analysis of standard and molybdenum-modified mar-m509 superalloys. J Test Eval. 1977;5(3):217–223.
- Donachie MJ, Donachie SJ. Superalloys: a technical guide, Vol. 2. Materials Park, OH: ASM International; 2002. 10.31399/asm.tb.stg2.9781627082679
- Pan P, Li T, Wang Y, et al. Effect of temperature on hot corrosion of nickel-based alloys for 700 °C A-USC power plants. Corros Sci. 2022;203:110350.
- Bordenet B. “High Temperature Corrosion in Gas Turbines: Thermodynamic Modelling and Experimental Results,” PhD thesis, Rheinisch-Westfälische Institute of Technology; 2004.
- Gleeson B, Pettit FS, Meier GH. Reinterpretation of type ii hot corrosion of co-base. Oxid Met. 2018;90(5):527–553.