Booth, G. C. and Clarke, R. L. (1986), ‘Evaluation of corrosion resistance of coated superalloys in rig tests’, Materials Science & Technology 2, 272–281.CrossRefGoogle Scholar

Boyce, M. P. (2012), Gas turbine engineering handbook, 4th edn, Butterworth-Heinemann, Oxford, 401–425 and 509–514.Google Scholar

Brau, W. (2009), ‘Environmental stability of the YSZ layer and the YSZ/TGO interface of an in-service EB-PVD coated high pressure turbine blade’, Journal of Materials Science 44, 1664–1675.CrossRefGoogle Scholar

Brau, W. and Mechnich, P. (2011), ‘Recession of an EB-PVD YSZ coated turbine blade by CaSO₄ and Fe, Ti rich CMAS-type deposits’, Journal of the American Ceramic Society 94 (12), 4483–4489.CrossRefGoogle Scholar

Bürgel, R. (1986), ‘Coating service experience with industrial gas turbines’, Materials Science & Technology 2, 302–308.CrossRefGoogle Scholar

Cetel, A. D. and Duhl, D. N. (1988), ‘Second generation nickel base single crystal superalloy’, in Superalloys TMS, Minerals, Metals & Materials Society.Google Scholar

Condé, J. F. G., Booth, G. C. and Taylor, A. F. (1986), ‘Protection against hot corrosion in marine gas turbines’, Materials Science & Technology 2, 314–317.CrossRefGoogle Scholar

Darolia, R. (2013), ‘Thermal barrier coatings technology: Critical review, progress update, remaining challenges and prospects’, International Materials Reviews 58 (6), 315–248.CrossRefGoogle Scholar

de Wet, D. J., Stott, F. H. and Taylor, R. (1993), ‘The degradation of ZrO2-Y2O3 thermal barrier coatings by molten middle east sand’, Surface Engineering, Volume II: Engineering Applications (based on the proceedings of the 3rd international conference on advances in coatings and surface engineering for corrosion and wear resistance), Royal Society of Chemistry, London, 210–219.Google Scholar

Fitzer, F. and Schlichting, J. (1983), ‘Coatings containing chromium, aluminium and silicon for high temperature alloys’, in High temperature corrosion, National Association of Corrosion Engineers (NACE), Houston, Texas, 604–614, edited by Rapp, R. A..Google Scholar

Goward, G. W. (1983), ‘Recent developments on high temperature coatings for gas turbine airfoils’, in High temperature corrosion, National Association of Corrosion Engineers (NACE), Houston, Texas, 553–560, edited by Rapp, R. A..Google Scholar

Goward, G. W. (1986), ‘Protective coatings – Purpose, role, and design’, Materials Science & Technology 2, 194–200.CrossRefGoogle Scholar

Goward, G. W. (1998), ‘Progress in coatings for gas turbine airfoils’, Surface Coatings & Technology 108 –109, 73–79.CrossRefGoogle Scholar

Grindle, T. J. and Burcham, F. W. (2003), ‘Engine damage to a NASA DC-8-72 airplane from a high altitude encounter with a diffuse volcanic ash cloud’, NASA Report TM-2003-212030.Google Scholar

Han, J. C., and Wright, L. M. (2007), ‘Enhanced internal cooling of turbine blade and vanes,’ The gas turbine handbook – U.S. DOE, National Energy Technology Laboratory, Morganton, USA, section 4-2-2-2, 321–35.Google Scholar

Hancock, P. (1986), ‘Future direction of research on high temperature coatings’, Materials Science & Technology 2, 310–313.CrossRefGoogle Scholar

Harris, and Wahl, (2004), ‘Improved single crystal superalloys, CMSX-4 (SLS)[La+Y] and CMSX-486’, in Superalloys 2004, TMS (The Minerals, Metals & Materials Society), edited by Green, K. A., Pollock, T. M. and Harada, H..Google Scholar

Harry, N. J. V. (1986), ‘Marine applications’, Materials Science & Technology 2, 295–301.CrossRefGoogle Scholar

Hutchings, I. J. (1992), ‘Tribology – Friction and wear of engineering materials’, Edward Arnold, London, 172–182.Google Scholar

Jordon, H. (and 9 others), (2004), ‘Superior thermal barrier coatings using solution precursor plasma spray’, Journal of Thermal Spray Technology 13 (1), 57–65.CrossRefGoogle Scholar

Kaden, U., Leyens, C., Peters, M. and Kaysser, W. A. (1999), ‘Thermal stability of an EB-PVD thermal barrier coating system on a single crystal nickel base superalloy’, in Elevated temperature coatings: Science & Technology III, The Metals & Minerals Society, 27–38, edited by Hampikian, J. M. and Dahotre, N. B..Google Scholar

Kircher, I. A., Mordie, B. G. and McCarter, A. (1994), ‘Performance of silicon modified aluminide coating in high temperature hot corrosion test conditions’, Surface and Coatings Technology 68 /69, 32–37.CrossRefGoogle Scholar

Leyens, C., Wright, I. G. and Pint, B. A. (1999), ‘Hot corrosion of nickel base alloys in biomass derived fuel simulated atmosphere’, in Elevated temperature coatings: Science & Technology III, The Metals & Minerals Society, 79–90, edited by Hampikian, J. M. and Dahotre, N. B..Google Scholar

Lotrakul, P., Trice, R. W., Trumble, K. P. and Dayananda, M. A. (2014), ‘Investigation of the mechanisms of Type-II hot corrosion of superalloy CMSX-4’, Corrosion Science 80, 408–415.CrossRefGoogle Scholar

Meetham, G. W. (1986), ‘Use of protective coatings in aero gas turbine engines’, Materials Science & Technology 2, 290–294.CrossRefGoogle Scholar

Ndamka, N. L. (2013), ‘Microstructural damage of thermal barrier coatings due to CMAS attack’, PhD thesis, Cranfield University, UK.Google Scholar

Ndamka, N. L. (2014), ‘Turbine blade coatings feel the heat’, Materials World, April, 30–33.Google Scholar

Nicholls, J. R., Deakin, M. J. and Rickerby, D. S. (1999), ‘A comparison between the erosion behaviour of thermal spray and electron beam physical vapour deposition thermal barrier coatings’, Wear 233 –235, 352–361.CrossRefGoogle Scholar

Nicholls, J. R., Simms, N. J., Chan, W. Y. and Evans, H. E. (2002), ‘Smart overlay coatings – Concept and practice’, Surface and Coatings Technology 149 (2–3), 236–244.CrossRefGoogle Scholar

Nicoll, A. R. (1982), ‘Self fluxing coatings for stationary gas turbines’, Thin Solid Films 95 (3), 285–295.CrossRefGoogle Scholar

Pettit, F. (2011), ‘Hot corrosion of metals and alloys’, Oxidation of Metals 76, 1–21.CrossRefGoogle Scholar

Rapp, R. A. (2002), ‘Hot corrosion of materials: A fluxing mechanism?’ Corrosion Science 44, 209–221.CrossRefGoogle Scholar

Saunders, S. R. J. (1986), ‘Correlation between laboratory and corrosion rig testing and service experience’, Materials Science & Technology 2, 282–289.CrossRefGoogle Scholar

Saunders, S. R. J. and Nicholls, J. R. (1984), ‘Hot salt corrosion test procedures and coating evaluation’, Thin Solid Films 119, 247–269.CrossRefGoogle Scholar

Saunders, S. R. J. and Nicholls, J. R. (1989), ‘Coatings and surface treatments for high temperature oxidation resistance’, Materials Science & Technology 5, 780–798.CrossRefGoogle Scholar

Schulz, U., Saruhan, B., Fritscher, K. and Leyens, C. (2004), ‘Review of advanced EB-PVD ceramic topcoats for TBC applications’, International Journal of Applied Creamic Technology 1 (4), 302–315.Google Scholar

Smith, A. B., Kempster, A. and Smith, J. (2000), Characterisation of aluminide coatings formed on nickel-base superalloys by vapour aluminising, IOM Communications, London, 13–27.Google Scholar

Tabakoff, W. (1999), ‘Erosion resistance of superalloys and different coatings exposed to particulate flows at high temperature’, Surface & Coating Technology 120 –121, 542–547.CrossRefGoogle Scholar

Tamarin, Y. (2006), Protective coatings for turbine blades, ASM International, Materials Park, Ohio, USA, 25–34.Google Scholar

Vialas, N. and Monceau, D. (2006), ‘Substrate effect on high temperature oxidation of Pt modified aluminide coating Part 1’, Oxidation of Metals 66 (3/4), 155–189.CrossRefGoogle Scholar

Wellman, R. G. and Nicholls, J. R. (2007), ‘A review of the erosion of thermal barrier coatings’, Journal of Physics D: Applied Physics 40, R293–R305.CrossRefGoogle Scholar

Wu, W. T., Rahmel, A. and Schorr, M. (1983), ‘Acidic and basic fluxing of Ni-base superalloys in a 90Na₂SO₄−10K₂SO₄ melt at 1173 K’, Oxidation of Metals 19 (5/6), 201–229.CrossRefGoogle Scholar

Wu, W. T., Rahmel, A. and Schorr, M. (1984), ‘Role of platinum in the Na₂SO₄ induced hot corrosion resistance of aluminium diffusion coatings’, Oxidation of Metals 22 (1/2), 59–81.CrossRefGoogle Scholar