References
- Choi J, Seok C-S, Park S, et al. Effect of high-temperature degradation on microstructure evolution and mechanical properties of austenitic heat-resistant steel. J Mater Res Technol. 2019;8:2011–2020.
- Zhang Y, Li M, Godlewski LA, et al. Effects of W on creep behaviors of novel Nb-bearing high nitrogen austenitic heat-resistant cast steels at 1000 °C. Mater Charact. 2018;139:19–29.
- Zhou Y, Liu Y, Zhou X, et al. Precipitation and hot deformation behavior of austenitic heat-resistant steels: a review. J Mater Sci Technol. 2017;33:1448–1456.
- Wang J, Qiao Y, Dong N, et al. The influence of temperature on the oxidation mechanism in air of HR3C and aluminum-containing 22Cr–25Ni austenitic stainless steels. Oxid Met. 2018;89:713–730.
- Jung S, Jo YH, Jeon C, et al. Effects of Mn and Mo addition on high-temperature tensile properties in high-Ni-containing austenitic cast steels used for turbo-charger application. Mater Sci Eng A. 2017;682:147–155.
- Jepson M, Higginson RL. The use of EBSD to study the microstructural development of oxide scales on 316 stainless steel. Mater High Temp. 2005;22:195–200.
- Ootani T, Yahata N, Fujiki A, et al. Impact wear characteristics of engine valve and valve seat insert materials at high temperature (impact wear tests of austenitic heat-resistant steel SUH36 against Fe-base sintered alloy using plane specimens). Wear. 1995;188:175–184.
- Zhang Y, Sun Y, Guan S, et al. Effect of titanium and tungsten on the structure and properties of heat-abrasion resistant steel. Mater Sci Eng A. 2008;478:214–220.
- Wei S, Xu L. Review on research progress of steel and iron wear-resistant materials. Acta Metall Sin. 2020;56:523–538.
- Van Gen Hassend F, Weber S. A Comparative study on the tribological properties of a cobalt-free superaustenitic stainless steel at elevated temperature. Metals (Basel). 2020;10:1123.
- Lee B, Song J, Hong S. High-temperature deformability of a Fe-Cr-Mn-Ni austenite stainless steel with high nitrogen and high carbon contents. Metals (Basel). 2018;8:608.
- Yamamoto Y, Santella ML, Liu CT, et al. Evaluation of Mn substitution for Ni in alumina-forming austenitic stainless steels. Mater Sci Eng A. 2009;524:176–185.
- Zhao X, Xing J, Zhou Q. Influence of C on oxiation and wear of Fe-Cr-Mn alloy at high temperatures. Acta Metall Sin. 1992;28:253–258.
- Bi H, Jiang X, Li S, et al. The corrosive wear behavior of Cr-Mn-N series casting stainless steel. Acta Metall Sin. 1997;33:1069–1074.
- Fischer A, Tikhovskiy I, Büscher R, et al. Mechanische und tribologische Eigenschaften von hochstickstoffhaltigen Austeniten. Materwiss Werksttech. 2006;37:747–754.
- Filippov MA, Belozerova TA, Blinov VM, et al. Effect of heat treatment on the wear resistance of high-carbon and high-nitrogen steels subjected to abrasive wear. Met Sci Heat Treat. 2006;48:170–174.
- Mujica Roncery L, Agudo Jácome L, Aghajani A, et al. Subsurface characterization of high-strength high-interstitial austenitic steels after impact wear. Wear. 2018;402–403:137–147.
- Kim K-S, Kang J-H, Kim S-J. Effects of carbon and nitrogen on precipitation and tensile behavior in 15Cr-15Mn-4Ni austenitic stainless steels. Mater Sci Eng A. 2018;712:114–121.
- Zhou W, Guo H, Xie Z, et al. High strength low-carbon alloyed steel with good ductility by combining the retained austenite and nano-sized precipitates. Mater Sci Eng A. 2013;587:365–371.
- Zhang C, Liu Y, Zhou L, et al. Secondary hardening, austenite grain coarsening and surface decarburization phenomenon in Nb-bearing spring steel. J Iron Steel Res Int. 2012;19:47–61.
- Yokomaku T, Saori M, Okuda T. Creep-fatigue properties of zirconium added HK40 and HP heat-resisting centrifugal cast alloys. Int J Fatigue. 1990;12:228.
- Barani AA, Li F, Romano P, et al. Design of high-strength steels by microalloying and thermomechanical treatment. Mater Sci Eng A. 2007;463:138–146.
- Feng Y, Song R, Peng S, et al. Microstructures and impact wear behavior of Al-alloyed high-Mn austenitic cast steel after aging Treatment. J Mater Eng Perform. 2019;28:4845–4855.
- Zhang Y, Sun Y, Zhao J, et al. Effects of Al on microstructure and high-temperature wear properties of austenitic heat-resistant steel. J Iron Steel Res Int. 2012;19:62–66.
- Sun Y, Lv Y, Wang L, et al. Effect of aluminum on microstructure and properties of martensitic wear-resistant and heat-resistant steel. Oxid Met. 2013;80:113–124.
- Kračun A, Jenko D, Godec M, et al. Nanoparticles Reinforcement for the improved strength and high-temperature wear resistance of Mn-Cr steel. Metall Mater Trans A. 2018;49:5683–5694.
- Vanderschaeve F, Taillard R, Foct J. Discontinuous precipitation of Cr2N in a high nitrogen, chromium-manganese austenitic stainless steel. J Mater Sci. 1995;30:6035–6046.
- Kikuchi M, Kajihara M, Choi S-K. Cellular precipitation involving both substitutional and interstitial solutes: cellular precipitation of Cr2N in Cr-Ni austenitic steels. Mater Sci Eng A. 1991;146:131–150.
- Presser R, Silcock JM. Aging behaviour of 18Mn–18Cr high nitrogen austenitic steel for end rings. Met Sci. 1983;17:241–248.
- Voice WE, Faulkner RG. The discontinuous precipitation of M23C6 in Nimonic 80A. J Mater Sci. 1987;22:4221–4232.
- Zheng L, Hu X, Kang X, et al. Precipitation of M23C6 and its effect on tensile properties of 0.3C–20Cr–11Mn–1Mo–0.35N steel. Mater Des. 2015;78:42–50.
- Lei J, Wu K, Li Y, et al. Effects of Zr addition on microstructure and toughness of simulated CGHAZ in high-strength low-alloy steels. J Iron Steel Res Int. 2019;26:1117–1125.
- Wen D, Jiang B, Wang Q, et al. Influences of Mo/Zr minor-alloying on the phase precipitation behavior in modified 310S austenitic stainless steels at high temperatures. Mater Des. 2017;128:34–46.
- Liu T, Lin Y, Zheng K, et al. Effect of minor Zr on oxidation resistance and mechanical property of nickel-saving austenitic heat-resistant cast steel. Mater Res Express. 2019;7:016514.
- Sullivan JL, Quinn TFJ, Rowson DM. Developments in the oxidational theory of mild wear. Tribol Int. 1980;13:153–158.
- Wilson JE, Stott FH, Wood GC, et al. The development of wear-protective oxides and their influence on sliding friction. Proc R Soc London A Math Phys Sci. 1980;369:557–574.
- Wang SQ, Wei MX, Wang F, et al. Transition of mild wear to severe wear in oxidative wear of H21 steel. Tribol Lett. 2008;32:67–72.
- Abouei V, Saghafian H, Kheirandish S. Dry sliding oxidative wear in plain carbon dual phase steel. J Iron Steel Res Int. 2007;14:43–48.
- Cui XH, Wang SQ, Wang F, et al. Research on oxidation wear mechanism of the cast steels. Wear. 2008;265:468–476.
- Mosecker L, Pierce DT, Schwedt A, et al. Temperature effect on deformation mechanisms and mechanical properties of a high manganese C+N alloyed austenitic stainless steel. Mater Sci Eng A. 2015;642:71–83.
- Lee T-H, Oh C-S, Kim S-J, et al. Deformation twinning in high-nitrogen austenitic stainless steel. Acta Mater. 2007;55:3649–3662.
- Kocks UF, Cook RE, Mulford RA. Strain aging and strain hardening in Ni-C alloys. Acta Metall. 1985;33:623–638.
- Wang Z, Baker I, Guo W, et al. The effect of carbon on the microstructures, mechanical properties, and deformation mechanisms of thermo-mechanically treated Fe40.4Ni11.3Mn34.8Al7.5Cr6 high entropy alloys. Acta Mater. 2017;126:346–360.
- Wang Z, Baker I, Cai Z, et al. The effect of interstitial carbon on the mechanical properties and dislocation substructure evolution in Fe40.4Ni11.3Mn34.8Al7.5Cr6 high entropy alloys. Acta Mater. 2016;120:228–239.
- Luo ZC, Huang MX. The role of interstitial carbon atoms on the strain-hardening rate of twinning-induced plasticity steels. Scr Mater. 2020;178:264–268.
- Radu I, Li DY. A further study of the beneficial effects of yttrium on oxide scale properties and high-temperature wear of Stellite 21. Tribol Lett. 2008;30:27–34.
- Stott FH. The role of oxidation in the wear of alloys. Tribol Int. 1998;31:61–71.
- Cao T, Fang X, Cheng C, et al. Creep behavior of two kinds of HR3C heat resistant steels based on stress relaxation tests. Acta Metall Sin. 2014;50:1343–1349.