[1] Jin J Y, Wang D, Chen X et al. Test and application of 60 kg·m-1 bainitic rail for heavy haul railway[J]. China Railway Science, 42, 34-40(2021).

[2] Zhang R J, Zheng C L, Zhang P J et al. Effect of segregation and contact stress on fatigue wear behavior of bainitic rail steel[J]. Journal of Mechanical Engineering, 59, 253-263(2023).

[3] Liu J P, Du H Q, Li Y Q et al. Effect of typical production process on microstructure and properties of carbide-free bainitic rail steels[J]. China Railway Science, 43, 29-37(2022).

[4] Li Y Q, Zhang Y H, Liu J P et al. Experimental study on wear and damage behavior of rail for heavy haul railway[J]. China Railway Science, 43, 152-160(2022).

[5] Jin F, Xiao H, Wang L J et al. Analysis on elastoplastic evolution characteristics of rail corrugation in small radius section of heavy-haul railway[J]. Journal of Central South University (Science and Technology), 54, 3358-3369(2023).

[6] Li J, Fan W G, Wu Z W et al. Contact behavior and material removal characteristics of abrasive belt grinding of contact wheels with different slotted for rail rehabilitation[J]. China Railway Science, 45, 47-55(2024).

[7] Yang B, Liao Z, Wu S C et al. Development of additive manufacturing technology and its application prospect in advanced rail transit equipment[J]. Journal of Traffic and Transportation Engineering, 21, 132-153(2021).

[8] Hu J K, Jiang Y J, Fang J K et al. Generalized predictive control of the grinding force of rail milling train[J]. China Railway Science, 35, 84-90(2014).

[9] Zhang W L, Fan X Q, Zhu M H et al. Development status and prospect of key rail grinding equipment and technology of grinding stone[J]. China Mechanical Engineering, 33, 2269-2287(2022).

[10] Piscopo G, Iuliano L. Current research and industrial application of laser powder directed energy deposition[J]. The International Journal of Advanced Manufacturing Technology, 119, 6893-6917(2022).

[11] Mortazavian E, Wang Z Y, Teng H L. Repair of light rail track through restoration of the worn part of the railhead using submerged arc welding process[J]. The International Journal of Advanced Manufacturing Technology, 107, 3315-3332(2020).

[12] Lai Q, Abrahams R, Yan W Y et al. Investigation of a novel functionally graded material for the repair of premium hypereutectoid rails using laser cladding technology[J]. Composites Part B: Engineering, 130, 174-191(2017).

[13] An T B, Wei J S, Zhao L et al. Influence of carbon content on microstructure and mechanical properties of 1000 MPa deposited metal by gas metal arc welding[J]. Journal of Iron and Steel Research International, 26, 512-518(2019).

[14] Yao Z S, Tian J Y, Chen X et al. Investigation on microstructure and properties of low-carbon wear-resistant steels with addition of Cr and Ni[J]. Steel Research International, 91, 1900677(2020).

[15] Xiao Q, Li S Y, Yang W B et al. High-temperature tribological properties of coatings repaired by laser additive manufacturing on railway wheel tread damage[J]. Wear, 520, 204674(2023).

[16] Zhu Y, Yang Y, Mu X et al. Study on wear and RCF performance of repaired damage railway wheels: assessing laser cladding to repair local defects on wheels[J]. Wear, 430, 126-136(2019).

[17] Yang W B, Li S Y, Xiao Q et al. Microstructure and properties of laser cladding coatings for ER9 wheel materials[J]. Chinese Journal of Lasers, 50, 0802202(2023).

[18] Kendall O, Abrahams R, Paradowska A et al. Influence of multi-layer laser cladding depositions and rail curvature on residual stress in light rail components[J]. Engineering Failure Analysis, 150, 107330(2023).

[19] Tomlinson K, Fletcher D I, Lewis R. Evaluation of laser cladding as an in situ repair method on rail steel[J]. Tribology International, 180, 108210(2023).

[20] Xiang C, Zhang T, Wu W W et al. Effect of heat treatment on microstructure and mechanical properties of selective laser melted 18Ni300 maraging steel[J]. Chinese Journal of Lasers, 51, 1602302(2024).

[21] Shim D S, Baek G Y, Lee S B et al. Influence of heat treatment on wear behavior and impact toughness of AISI M4 coated by laser melting deposition[J]. Surface and Coatings Technology, 328, 219-230(2017).

[22] Chen Y H. Study on microstructure and properties of laser rapid manufacturing CrNiMoTi low alloy steels[D], 48-49(2018).

[23] Guo Y B, Li Z G, Yao C W et al. Microstructure evolution of Fe-based nanostructured bainite coating by laser cladding[J]. Materials & Design, 63, 100-108(2014).

[24] Tang Y C, Yang H C, Huang D S et al. Dual-gradient bainite steel matrix composite fabricated by direct laser deposition[J]. Materials Letters, 238, 210-213(2019).

[25] Zhao M J, Jiang X, Guan Y M et al. Enhanced hardness-toughness balance induced by adaptive adjustment of the matrix microstructure in in situ composites[J]. Materials, 16, 4437(2023).

[26] Yin W J, Briffod F, Yamazaki K et al. Effect of limited retained austenite on the strength-ductility trade-off in low-alloyed TRIP steel[J]. Materials Science and Engineering: A, 861, 144337(2022).

[27] Srivastava A K, Jha G, Gope N et al. Effect of heat treatment on microstructure and mechanical properties of cold rolled C-Mn-Si TRIP-aided steel[J]. Materials Characterization, 57, 127-135(2006).

[28] Long S L, Liang Y L, Jiang Y et al. Effect of quenching temperature on martensite multi-level microstructures and properties of strength and toughness in 20CrNi2Mo steel[J]. Materials Science and Engineering: A, 676, 38-47(2016).

[29] Baek M S, Kim K S, Park T W et al. Quantitative phase analysis of martensite-bainite steel using EBSD and its microstructure, tensile and high-cycle fatigue behaviors[J]. Materials Science and Engineering: A, 785, 139375(2020).

[30] Wang Y Z, Hua J J, Kong M G et al. Quantitative analysis of martensite and bainite microstructures using electron backscatter diffraction[J]. Microscopy Research and Technique, 79, 814-819(2016).

[31] Zhang W, Dong Z, Kang H et al. Effect of various quenching treatments on microstructure and mechanical behavior of a laser additively manufactured 12CrNi2 alloy steel[J]. Journal of Materials Processing Technology, 288, 116907(2021).

[32] Zhao Y S, Ding C G. Effect of heat treatment on microstructure and properties of 24CrNiMo alloy steel formed by selective laser melting (SLM)[J]. Materials, 14, 631(2021).

[33] Zhou L, Chen S Y, Wei M W et al. Microstructure and properties of 24CrNiMoY alloy steel prepared by direct laser deposited under different preheating temperatures[J]. Materials Characterization, 158, 109931(2019).

[34] Heng Z, Shu L S. Effect of laser power on mechanical properties of laser cladded 27SiMn steel[J]. Chinese Journal of Lasers, 49, 0802011(2022).

[35] Shi S, Huang C P, Liu F G et al. Effect of heat treatment on microstructure and mechanical properties of 34CrNiMo6 steel by laser solid forming[J]. Journal of Manufacturing Processes, 78, 308-318(2022).

[36] Liu Z H, Zhu X B, Xia J Q et al. Microstructure and properties of 30CrMnSi steel manufactured by selective laser melting[J]. Hot Working Technology, 50, 59-63(2021).

[37] Liu Y D, Li P Y, Shi W T et al. Impact of interval remelting on TC4 selective laser melting samples[J]. Laser & Optoelectronics Progress, 60, 0514009(2023).

[38] Zhang D Y, Feng Z, Wang C J et al. Modeling of temperature field evolution during multilayered direct laser metal deposition[J]. Journal of Thermal Spray Technology, 26, 831-845(2017).

[39] Gao B, Tan Z L, Tian Y et al. Accelerated isothermal phase transformation and enhanced mechanical properties of railway wheel steel: the significant role of pre-existing bainite[J]. Steel Research International, 93, 2100494(2022).

[40] Tan C L, Li Q, Yao X L et al. Machine learning customized novel material for energy-efficient 4D printing[J]. Advanced Science, 10, e2206607(2023).

[41] Zhao H S, Li W, Wang L et al. The deformation behavior analysis and mechanical modeling of step/intercritical quenching and partitioning-treated multiphase steels[J]. Metallurgical and Materials Transactions A, 47, 3943-3955(2016).

[42] Sakamaki T, Tanaka M, Morikawa T et al. Brittle-to-ductile transition in martensite-bainite steel[J]. ISIJ International, 61, 2167-2175(2021).

[43] Wang Y C, Wu K M. Effect of tempering temperature on the mechanical properties of ultra-high strength and toughness hull structural steel[J]. Journal of Wuhan University of Science and Technology, 42, 328-333(2019).