[1] X.Y. Tang, S.Z. Wang, L.L. Qian, Y.H. Li, Z.H. Lin, D.H. Xu, Y.P. zhang, Corrosion behavior of nickel base alloys, stainless steel and titanium alloy in supercritical water containing chloride, phosphate and oxygen, Chem. Eng. Res. Des. 100 (2015) 530–541. [2] M.V. Gunaji, S. Sircar, H.D. Beeson, Ignition and combustion of titanium and titanium alloys, in: Proceedings of the Symposium on Flammability and Sensitivity of Materials in Oxygen-Enriched Atmospheres, Denver, CO, USA, 1995. [3] J.L. Yu, X.Y. Zhang, Q. Zhang, L.B. Wang, K. Ji, L. Peng, W. Gao, Combustion behaviors and flame microstructures of micro- and nano-titanium dust explosions, Fuel 181 (2016) 785–792. [4] L.A. Villegas-Armenta, R.A.L. Drew, M.O. Pekguleryuz, The ignition behavior of Mg–Ca binary alloys: The role of heating rate, Oxid. Met. 93 (5–6) (2020) 545–558. [5] T.A. Brzustowski, I. Glassman, Spectroscopic investigation of metal combustion, in: H.G. Wolfhard, I. Glassman, L. Green (Eds.), Progress in Astronautics and Rocketry, Elsevier, 1964, pp. 41–73. [6] X.R. Zou, N.F. Wang, L.J. Liao, Q.Z. Chu, B.L. Shi, Prediction of nano/micro aluminum particles ignition in oxygen atmosphere, Fuel 266 (2020) 116952. [7] V.I. Bolobov, Possible mechanism of autoignition of titanium alloys in oxygen, Combust. Explos. Shock. Waves 39 (6) (2003) 677–680. [8] G.B. Mi, X. Huang, J.X. Cao, C.X. Cao, X.S. Huang, Frictional ignition of Ti40 fireproof titanium alloys for aero-engine in oxygen-containing media, Trans. Nonferrous Met. Soc. China 23 (8) (2013) 2270–2275. [9] F. Motte, C. Coddet, P. Sarrazin, M. Azzopardi, J. Besson, A comparative study of the oxidation with water vapor of pure titanium and of Ti-6Al-4V, Oxid. Met. 10 (2) (1976) 113–126. [10] J.E.L. Gomes, A.M. Huntz, Correlation between the oxidation mechanism of titanium under a pure oxygen atmosphere, morphology of the oxide scale, and diffusional phenomena, Oxid. Met. 14 (3) (1980) 249–261. [11] S. Özel, E. Vural, M. Binici, Optimization of the effect of thermal barrier coating (TBC) on diesel engine performance by Taguchi method, Fuel 263 (2020) 116537. [12] D.C. Lagoudas, P. Entchev, R. Triharjanto, Modeling of oxidation and its effect on the crack growth resistance of titanium alloys, Stud. Appl. Mech. 46 (1998) 421–440. [13] R. Braun, M. Fröhlich, W. Braue, C. Leyens, Oxidation behaviour of gamma titanium aluminides with EB-PVD thermal barrier coatings exposed to air at 900 ℃, Surf. Coat. Technol. 202 (4–7) (2007) 676–680. [14] A. Ebach-Stahl, C. Eilers, N. Laska, R. Braun, Cyclic oxidation behaviour of the titanium alloys Ti-6242 and Ti-17 with Ti-Al-Cr-Y coatings at 600 and 700 ℃ in air, Surf. Coat. Technol. 223 (2013) 24–31. [15] D. Kim, D. Seo, X. Huang, T. Sawatzky, H. Saari, J. Hong, Y. W. Kim, Oxidation behaviour of gamma titanium aluminides with or without protective coatings. International Materials Reviews, 2014. 59(6) 297-325. [16] P.K. Wright, Influence of cyclic strain on life of a PVD TBC, Mater. Sci. Eng. A 245 (2) (1998) 191–200. [17] M.P. Bacos, P. Josso, N. Vialas, D. Poquillon, B. Pieraggi, D. Monceau, J.R. Nicholls, N. Simms, A. Encinas-Oropesa, T. Ericsson, S. Stekovic, ALLBATROS advanced long life blade turbine coating systems, Appl. Therm. Eng. 24 (11–12) (2004) 1745–1753. [18] A.G. Evans, G.B. Crumley, R.E. Demaray, On the mechanical behavior of brittle coatings and layers, Oxid. Met. 20 (5–6) (1983) 193–216. [19] S. Punnose, A. Mukhopadhyay, R. Sarkar, Z. Alam, D. Das, V. Kumar, Determination of critical strain for rapid crack growth during tensile deformation in aluminide coated near-α titanium alloy using infrared thermography, Mater. Sci. Eng. A 576 (2013) 217–221. [20] K. Yamamoto, Y. Kawaguchi, T. Yasunaga, T. Sato, Cracking behavior of AIP-coated metal nitrides under tensile stress, Surf. Coat. Technol. 113 (3) (1999) 227–232. [21] I.A. Polonsky, L.M. Keer, Numerical analysis of the effect of coating microstructure on three-dimensional crack propagation in the coating under rolling contact fatigue conditions, J. Tribol. 124 (1) (2002) 14–19. [22] M. Eshraghi, S.D. Felicelli, An implicit lattice Boltzmann model for heat conduction with phase change, Int. J. Heat Mass Transf. 55 (9–10) (2012) 2420–2428. [23] J.A. Huang, C. Bao, Z.Y. Jiang, X.X. Zhang, A general approach of unit conversion system in lattice Boltzmann method and applications for convective heat transfer in tube banks, Int. J. Heat Mass Transf. 135 (2019) 873–884. [24] P. Zhou, Z.C. Liu, W. Liu, X.L. Duan, LBM simulates the effect of sole nucleate site geometry on pool boiling, Appl. Therm. Eng. 160 (2019) 114027. [25] P.L. Bhatnagar, E.P. Gross, M. Krook, A model for collision processes in gases. I. small amplitude processes in charged and neutral one-component systems, Phys. Rev. 94 (3) (1954) 511–525. [26] S.C. Mishra, A. Lankadasu, K.N. Beronov, Application of the lattice Boltzmann method for solving the energy equation of a 2-D transient conduction-radiation problem, Int. J. Heat Mass Transf. 48 (17) (2005) 3648–3659. [27] Z.L. Guo, T.S. Zhao, A lattice boltzmann model for convection heat transfer in porous media, Numer. Heat Transf. B Fundam. 47 (2) (2005) 157–177. [28] J.J. Wang, Q.J. Kang, Y.Z. Wang, R. Pawar, S.S. Rahman, Simulation of gas flow in micro-porous media with the regularized lattice Boltzmann method, Fuel 205 (2017) 232–246. [29] Z. Guo, C. Shu, Lattice Boltzmann method and its applications in engineering, in: Advance in Computational Fluid Dynamics, World Scientific Publishing Co. Pte. Ltd, Singapore, 2013. [30] M. Yousaf, S. Usman, Natural convection heat transfer in a square cavity with sinusoidal roughness elements, Int. J. Heat Mass Transf. 90 (2015) 180–190. [31] C.K. Law, Recent advances in droplet vaporization and combustion, Prog. Energy Combust. Sci. 8 (3) (1982) 171–201. [32] B.I. Khaikin, V.N. Bloshenko, A.G. Merzhanov, On the ignition of metal particles, Combust. Explos. Shock. Waves 6 (4) (1970) 412–422. [33] E. Chicardi, J.M. Córdoba, F.J. Gotor, Kinetics of high-temperature oxidation of (Ti, Ta)(C, N)-based cermets, Corros. Sci. 102 (2016) 168–177. [34] J. Mularski, H. Pawlak-Kruczek, N. Modlinski, A review of recent studies of the CFD modelling of coal gasification in entrained flow gasifiers, covering devolatilization, gas-phase reactions, surface reactions, models and kinetics, Fuel 271 (2020) 117620. |