[1] Li J A, Yan H Z, Li S B et al. Structural characteristics and sliding friction properties of 40CrNiMo steel after broadband laser hardening[J]. Coatings, 11, 1282(2021).

[2] Babu P D, Marimuthu P. Status of laser transformation hardening of steel and its alloys: a review[J]. Emerging Materials Research, 8, 188-205(2019).

[3] Chen S X, Lei W N, Ren W B et al. Microstructures and performance of laser cladding and quenching remanufactured cladding layer on QT700 ductile cast iron gear surface[J]. Laser & Optoelectronics Progress, 58, 0514003(2021).

[4] Lin Y H, Yuan Y, Wang L et al. Effect of electric-magnetic compound field on the microstructure and crack in solidified Ni60 alloy[J]. Acta Metallurgica Sinica, 54, 1442-1450(2018).

[5] Lu H, Ren Y P, Chen Y et al. Wear resistance of 20Cr2Ni4A alloy steel treated by laser shock peening and implantation of diamond nanoparticles[J]. Surface and Coatings Technology, 412, 127070(2021).

[6] Li Q L, Shi S M, Li X et al. Study on low velocity cyclic impact wear of amorphous carbon films with different mechanical properties[J]. Surface and Coatings Technology, 402, 126339(2020).

[7] Chen C L, Feng A X, Liu B J et al. Effect of quench-tempering and laser quenching on the microstructure and properties of high-chromium cast iron[J]. Journal of Materials Research and Technology, 19, 2759-2773(2022).

[8] Cecchel S, Ferrario D, Cornacchia G et al. Development of heat treatments for selective laser melting Ti6Al4V alloy: effect on microstructure, mechanical properties, and corrosion resistance[J]. Advanced Engineering Materials, 22, 2000359(2020).

[9] He B, Shao W P, Tian X J. Surface grain formation mechanism in the laser remelting molten pool of a near-β titanium alloy[J]. Materialia, 24, 101521(2022).

[10] Wang S, Yan S, Lin J et al. Study on the effects of laser quenching power and scanning speed on the property of cast iron[J]. Journal of Physics: Conference Series, 2198, 012050(2022).

[11] Cui C, Wu M P, Xia S H. Effect of heat treatment on properties of laser cladding cobalt-based coating on 42CrMo steel surface[J]. Chinese Journal of Lasers, 47, 0602011(2020).

[12] Rathmann L, Radel T. Influence of laser hardening on laser induced periodic surface structures on steel substrates[J]. IOP Conference Series: Materials Science and Engineering, 1135, 012024(2021).

[13] Ping X L, Fu H G, Wang K M et al. Effect of laser quenching on microstructure and properties of the surface of track materials[J]. Surface Review and Letters, 25, 1950030(2018).

[14] Jin R Z. Application of advanced laser quenching technology in machine tool parts[J]. MW Metal Forming, 46-49(2016).

[15] Zhang Q L, Lin J, Chen Z J et al. Phase transformation process of electromagnetic induction assisted laser quenching based on MSC. Marc software[J]. Chinese Journal of Lasers, 48, 1103002(2021).

[16] Zhang Q L, Huang H, Tang Z H et al. Rolling wear and fatigue damage behavior of laser-induction hybrid quenching on 42CrMo steel[J]. Chinese Journal of Lasers, 49, 250-261(2022).

[17] Maharjan N, Zhou W, Zhou Y et al. Underwater laser hardening of bearing steels[J]. Journal of Manufacturing Processes, 47, 52-61(2019).

[18] Hu X F, Qu S G, Chen Z T et al. Rolling contact fatigue behaviors of 25CrNi2MoV steel combined treated by discrete laser surface hardening and ultrasonic surface rolling[J]. Optics & Laser Technology, 155, 108370(2022).

[19] Chen R, Wang H M, Li J et al. Effect of laser remelting and heat treatment on microstructure and wear resistance of 2A97 Al-Li alloy[J]. Surfaces and Interfaces, 33, 102197(2022).

[20] Zhen Y B, Cheng L, Chang S et al. Study on laser quenching technology and its application[J]. MW Metal Forming, 63-66(2018).

[21] Xu J L, Zou P, Liu L et al. Investigation on the mechanism of a new laser surface structuring by laser remelting[J]. Surface and Coatings Technology, 443, 128615(2022).

[22] Zhang Q L, Tong W H, Chen Z J et al. Effect of spot size on geometrical characteristics of laser deep quenching hardened layer of 42CrMo steel[J]. Surface Technology, 49, 254-261(2020).

[23] Xie J C, Raoelison R N, Zhang Y B et al. Mesoscopic segregation in H13 steel molten pool during laser remelting: a combined influence of Marangoni convection and oxidation[J]. Journal of Materials Processing Technology, 316, 117956(2023).

[24] Xie J C, Raoelison R N, Di R F et al. Laser remelting of AISI H13 tool steel: influence of cooling rate on the surface properties[J]. Surface Topography: Metrology and Properties, 10, 044003(2022).

[25] Liverani E, Ascari A, Fortunato A. Multilayered WC-Co coatings by direct energy deposition-based cladding: effect of laser remelting on interface defects[J]. Surface and Coatings Technology, 464, 129556(2023).

[26] Stormvinter A, Hedström P, Borgenstam A. A transmission electron microscopy study of plate martensite formation in high-carbon low alloy steels[J]. Journal of Materials Science & Technology, 29, 373-379(2013).

[27] Sugiyama M, Takei M, Sekida S et al. Characterization of hierarchical lath martensite microstructure in low carbon steels using ultra-high voltage TEM and SEM-EBSD analysis[J]. IOP Conference Series: Materials Science and Engineering, 1249, 012020(2022).

[28] Yang Z X, Wang A H, Xiong D H et al. Laser wide-band hardening of steel rails and corresponding fatigue wear property[J]. China Mechanical Engineering, 30, 254-260(2019).

[29] Yang Z, Fan X F, Qiu C J et al. Microstructure and properties of 40CrNiMoA steel surface after laser quenching[J]. Laser & Optoelectronics Progress, 57, 011405(2020).

[30] Li Z Y, Zhang J, Dai B Q et al. Microstructure and corrosion resistance property of laser transformation hardening pre-hardened AISI P20 plastic die steel[J]. Optics & Laser Technology, 122, 105852(2020).

[31] Liu Q B, Zhou F, Xu P[M]. Laser material processing and its application(2018).

[32] Mi X L. Thermal laser quenching process of industrial machine in 2738 mold steel[D], 56-65(2021).