[1] Zhang H Q, Liu H, Liu Y et al. Research status and analysis of co-based composite coatings prepared by laser cladding[J]. Laser & Optoelectronics Progress, 60, 0900004(2023).

[2] Zan S P, Jiao J K, Zhang W W. Study on laser cladding process of 316L stainless steel powder[J]. Laser & Optoelectronics Progress, 53, 061406(2016).

[3] Li K, Fang J H, Liao R B et al. Current research status and future prospects for high-performance metal laser-energy-field surface heat treatment technologies (invited)[J]. Chinese Journal of Lasers, 51, 0402202(2024).

[4] Nie M H, Zhang S, Wang Z Y et al. Effect of laser power on microstructure and interfacial bonding strength of laser cladding 17-4PH stainless steel coatings[J]. Materials Chemistry and Physics, 275, 125236(2022).

[5] Wu C L, Zhang S, Zhang C H et al. Phase evolution characteristics and corrosion behavior of FeCoCrAlCu-X0.5 coatings on cp Cu by laser high-entropy alloying[J]. Optics & Laser Technology, 94, 68-71(2017).

[6] Fang P X, Zhang J, Xin W B et al. Phase composition and structure and high-temperature oxidation resistance of the Hf-modified MCrAlY bond coating alloy[J]. Materials Reports, 39, 1-11(2024).

[7] Zhang G S, Zhang Z J, Xuan J Y et al. The elevated temperature oxidation and wear behavior of Fe20Co20Ni20Cr8Mo12B10Si10 high-entropy alloy coating by laser cladding[J]. Journal of Materials Research and Technology, 29, 4216-4231(2024).

[8] Lou L Y, Zhang Y, Jia Y J et al. High speed laser cladded Ti-Cu-NiCoCrAlTaY burn resistant coating and its oxidation behavior[J]. Surface and Coatings Technology, 392, 125697(2020).

[9] Cui Y, Shen J Q, Manladan S M et al. Wear resistance of FeCoCrNiMnAlx high-entropy alloy coatings at high temperature[J]. Applied Surface Science, 512, 145736(2020).

[10] Zhao W, Li Z, Song C X et al. Al and Mo synergistic enhancement of CoCrFeNi high-entropy alloy laser cladding layer[J]. Journal of Materials Research and Technology, 28, 2572-2581(2024).

[11] Ma Q. Investigation on the synergistic effects of Ti/Nb/V and Zr elements on the microstructure and properties of high entropy alloy laser cladding layers[D](2024).

[12] Li Y S. High temperature oxidation and chlorination of metallic materials[D](2001).

[13] Adomako N K, Kim J H, Hyun Y T. High-temperature oxidation behaviour of low-entropy alloy to medium- and high-entropy alloys[J]. Journal of Thermal Analysis and Calorimetry, 133, 13-26(2018).

[14] Ma Q, Zhao W, Shi C W et al. Effect of synergistic variation in Ti and Zr elements on the microstructure and properties of laser cladding AlCoCrFeNi high-entropy alloy coatings[J]. Materials Characterization, 205, 113300(2023).

[15] Feng Y Q, Ye J L, Feng Y L et al. Microstructure evolution and high temperature oxidation behavior of laser cladded titanium-based composite modified by Nb/Si addition[J]. Surface and Coatings Technology, 444, 128677(2022).

[16] Huang Y B, Hu Y L, Zhang M J et al. On the enhanced wear resistance of laser-clad CoCrCuFeNiTix high-entropy alloy coatings at elevated temperature[J]. Tribology International, 174, 107767(2022).

[17] Wen Y. Study on the composition design and properties of high entropy alloys based on chromite[D]. Fuxin(2022).

[18] Zhang S, Qi W J, Zhang R. Effect of Ti content on wear and high-temperature oxidation resistances of laser-clad CoCrMoNbTix high-entropy alloy coatings[J]. Materials Letters, 345, 134490(2023).

[19] Huang B, Li X, Xie X Q et al. High temperature oxidation behavior and failure mechanism of silicide diffusion coating deposited on TC4 alloy[J]. Rare Metal Materials and Engineering, 50, 544-551(2021).

[20] Ren B. Study on microstructure and mechanical properties of laser additive manufactured and heat treated CoCrW alloy[D](2018).

[21] Zhang J, Liu Z D, Ma H R et al. Effect of Si on high temperature oxidation characteristics of laser cladding 625 alloy[J]. Rare Metal Materials and Engineering, 51, 3602-3610(2022).

[22] Huang S X, Yu Y D, Wei N X et al. Microstructure and properties of MoSiNi-SiC composite coating on nickel-based alloy by laser cladding[J]. Applied Laser, 42, 28-35(2022).

[23] Li Y W, Wang T L. Exploring the characteristics and development prospects of high temperature ceramic material[J]. Shandong Chemical Industry, 53, 113-115(2024).

[24] Li S, Yamaguchi T. High-temperature oxidation performance of laser-cladded amorphous TiNiSiCrCoAl high-entropy alloy coating on Ti-6Al-4V surface[J]. Surface and Coatings Technology, 433, 128123(2022).

[25] Li J, Cui X F, Guan Y J et al. Analysis of oxidation behavior of laser cladding SiC-Ti based composite strengthening coating[J]. Materials Characterization, 204, 113210(2023).

[26] Niu Q Q, Liu X B, Xie X M et al. Tribological properties and oxidation resistance of laser cladded Ni60/SiC composite coatings on Inconel 718 alloy[J]. Tribology, 45, 1-13(2025).

[27] Fu Y H. Tribology and high-temperature oxidation resistance of nano-SiC partiulate-reinforced Ti-Al coating on titanium alloy surface by laser cladding technology[D](2020).

[28] Yu C Z, Zhu S L, Wei D Z et al. Amorphous sol-gel SiO2 film for protection of Ti6Al4V alloy against high temperature oxidation[J]. Surface and Coatings Technology, 201, 5967-5972(2007).

[29] Dong G, You H X, Mao K J et al. Effect of Si element content on the manufacturing process and corrosion performance of laser clad 316L[J]. Surface Technology, 53, 179-190(2024).

[30] Wang W Z. Effect of continuous component gradient Al, Ti and Cr on the high-temperature oxidation process and oxidation mechanism of Ni-Cr-Co based superalloys[D](2024).

[31] Wang L X, Huang Y M, Yuan Y X et al. Microstructure, wear and oxidation resistance of Al-doped Ti-Si3N4 coatings by laser cladding[J]. Surface and Coatings Technology, 429, 127942(2022).

[32] Dai J J, Li S Y, Zhang H X et al. Microstructure and high-temperature oxidation resistance of Ti-Al-Nb coatings on a Ti-6Al-4V alloy fabricated by laser surface alloying[J]. Surface and Coatings Technology, 344, 479-488(2018).

[33] Gorr B, Mueller F, Christ H J et al. High temperature oxidation behavior of an equimolar refractory metal-based alloy 20Nb-20Mo-0Cr-20Ti-20Al with and without Si addition[J]. Journal of Alloys and Compounds, 688, 468-477(2016).

[34] Li J Y, Fan J K, Song Y L et al. Research progress on the hot corrosion behavior and improvement method of single crystal superalloys[J]. Foundry Technology, 43, 841-855(2022).

[35] Xu Z M, Sun Z P, Li C et al. Effect of Cr on microstructure and properties of WVTaTiCrx refractory high-entropy alloy laser cladding[J]. Materials, 16, 3060(2023).

[36] Yang Y, Wang A H, Xiong D H et al. Effect of Cr content on microstructure and oxidation resistance of laser-clad Cu-Ni-Fe-Mo-xCr alloy coating[J]. Surface and Coatings Technology, 384, 125316(2020).

[37] Naveed M, Renteria A F, Weiß S. Role of alloying elements during thermocyclic oxidation of β/γ-TiAl alloys at high temperatures[J]. Journal of Alloys and Compounds, 691, 489-497(2017).

[38] Li S, Yamaguchi T. High-temperature oxidation behavior of laser-cladded refractory NiSi0.5CrCoMoNb0.75 high-entropy coating[J]. Journal of Materials Research and Technology, 17, 1616-1627(2022).

[39] Zhao Y S. Structural characteristics and high temperature oxidation resistance of laser cladding Ti-Al-B coating[D](2019).

[40] Chen T T, Shi Y J, Liu Z T et al. Role of nitrogen and tantalum in the high-temperature oxidation behavior of AlCoCr0.5NiTaxTi(N) alloys synthesized by laser in situ synthesis[J]. Surface and Coatings Technology, 486, 130953(2024).

[41] Yu K D, Zhao W, Li Z et al. High-temperature oxidation behavior and corrosion resistance of in situ TiC and Mo reinforced AlCoCrFeNi-based high entropy alloy coatings by laser cladding[J]. Ceramics International, 49, 10151-10164(2023).

[42] Sun D, Cai Y C, Zhu L S et al. High-temperature oxidation and wear properties of TiC-reinforced CrMnFeCoNi high entropy alloy composite coatings produced by laser cladding[J]. Surface and Coatings Technology, 438, 128407(2022).

[43] Xiong J K, Sun D, Dong N et al. Oxidation mechanism of TiC reinforced CrMnFeCoNi composite coatings by laser cladding at 600 ℃/750 ℃/900 ℃[J]. Materials Letters, 324, 132710(2022).

[44] Zhang M, Wang X H, Liu S S et al. Microstructure and high-temperature properties of Fe-Ti-Cr-Mo-B-C-Y2O3 laser cladding coating[J]. Journal of Rare Earths, 38, 683-688(2020).

[45] Ashtari P, Ahmadi N P, Yazdani S. Isothermal oxidation kinetics of laser cladded NiCoCrAl/WC + La2O3 hybrid composite coatings at 700 ℃[J]. Metallic Materials, 59, 269-278(2021).

[46] Li Z, Zhao W, Yu K D et al. Effect of Y2O3 on microstructure and properties of CoCrFeNiTiNb high entropy alloy coating on Ti-6Al-4V surface by laser cladding[J]. Journal of Rare Earths, 42, 586-599(2024).

[47] Han B. Effect of CeO2 on microstructure and properties of Fe-based composite coatings on die by laser cladding[D](2021).

[48] Ni J Y. Fabrication of FeCrAlY coatings based on high-power impulsed magnetron sputtering[D](2022).

[49] Zhao G M, Wang K L. Effect of La2O3 on resistance to high-temperature oxidation of laser clad ferrite-based alloy coatings[J]. Surface and Coatings Technology, 190, 249-254(2005).

[50] Feng Y Q, Feng K, Yao C W et al. Effect of LaB6 addition on the microstructure and properties of (Ti3Al+TiB)/Ti composites by laser cladding[J]. Materials & Design, 181, 107959(2019).

[51] Sun C C. Research on preparation and high-temperature protectiveness of NiAl cladded coatings reinforced by ceria nano-particles[D](2016).

[52] Liu K, Lou L, Cai Z et al. High temperature oxidation behavior of NiCoCrAlFeY high entropy bond coating fabricated by high - speed laser cladding[J]. Corrosion Science, 226, 111659(2024).

[53] Xu Q L, Zhang Y, Liu S H et al. High-temperature oxidation behavior of CuAlNiCrFe high-entropy alloy bond coats deposited using high-speed laser cladding process[J]. Surface and Coatings Technology, 398, 126093(2020).

[54] Hu Z Y, Li Y, Liu J et al. Research progress of ultra-high-speed laser cladding coating forming and key properties[J]. Laser & Optoelectronics Progress, 60, 0100003(2023).

[55] Zhang X Z, Sun Y C, Yu G X et al. Microstructural evolution and high-temperature oxidation of TiC/IN625 coatings fabricated by multi-layer extreme high-speed laser cladding[J]. Optics & Laser Technology, 158, 108838(2023).

[56] Yu J T, Sun W L, Yu S L et al. Comparative studies on microstructural characteristics and wear behavior of high-speed and low-speed laser cladding graphene/CoCrFeMo0.5NiTi0.5 high-entropy alloy composite layers[J]. Materials Today Communications, 39, 108970(2024).

[57] Chen L, Zhang X Z, Wu Y et al. Effect of surface morphology and microstructure on the hot corrosion behavior of TiC/IN625 coatings prepared by extreme high-speed laser cladding[J]. Corrosion Science, 201, 110271(2022).

[58] Cai J, Yao Y M, Gao C Z et al. Comparison of microstructure and oxidation behavior of NiCoCrAlYSi laser cladding coating before and after high-current pulsed electron beam modification[J]. Journal of Alloys and Compounds, 881, 160651(2021).

[59] Yao Y M, Cai J, Gao J et al. Thermal cycling behavior and stress distribution in TGO layer of MCrAlYX-type coatings via high-current pulsed electron beam modification[J]. Applied Surface Science, 605, 154674(2022).

[60] Li X C, Zhu W K, Shen H et al. Microstructures and high-temperature oxidation behavior of laser cladded NiCoCrAlYSi coating on Inconel 625 Ni-based superalloy modified via high current pulsed electron beam[J]. Surface and Coatings Technology, 427, 127796(2021).

[61] Cai J, Li C, Yao Y M et al. Microstructural modifications and high-temperature oxidation resistance of arc ion plated NiCoCrAlYSiHf coating via high-current pulsed electron beam[J]. Corrosion Science, 182, 109281(2021).

[62] Chen J, Yao Z H, Yao J H et al. State-of-art review on ultrasonic vibration-assisted laser cladding[J]. Aeronautical Manufacturing Technology, 64, 36-46(2021).

[63] Mohsan A U H, Zhang M N, Wang D F et al. State-of-the-art review on the ultrasonic vibration assisted laser cladding (UVALC)[J]. Journal of Manufacturing Processes, 107, 422-446(2023).

[64] Wang Y K, Zhang M N, Wang D F et al. Advances in ultrasonic vibration-assisted metal melting and forming technology[J]. Chinese Journal of Lasers, 51, 2402101(2024).

[65] Jin M, He D Y, Shao W et al. The microstructure and high-temperature oxidation resistance of Si-rich Mo-Si-B coatings prepared by ultrasonic vibration assisted laser cladding[J]. Journal of Alloys and Compounds, 953, 170175(2023).

[66] Tzanakis I, Lebon G S B, Eskin D G et al. Investigation of the factors influencing cavitation intensity during the ultrasonic treatment of molten aluminium[J]. Materials & Design, 90, 979-983(2016).

[67] Zhang M, Zhao G L, Wang X H et al. Microstructure evolution and properties of in situ ceramic particles reinforced Fe-based composite coating produced by ultrasonic vibration assisted laser cladding processing[J]. Surface and Coatings Technology, 403, 126445(2020).

[68] Zhang N. Study on the effect of electromagnetic composite field on the distribution of pore and WC particles in cladding layer[D](2019).

[69] Xu J L. Study on microstructure and properties of Co-based coatings by laser cladding coupled with electromagnetic/ultrasonic compound energy field[D](2019).