[1] Jiang J H, Zhou Q, Yu J S et al. Comparative analysis for corrosion resistance of micro-arc oxidation coatings on coarse-grained and ultra-fine grained AZ91D Mg alloy[J]. Surface and Coatings Technology, 216, 259-266(2013).

[2] Miura H, Maruoka T, Jonas J J. Effect of ageing on microstructure and mechanical properties of a multi-directionally forged Mg-6Al-1Zn alloy[J]. Materials Science and Engineering: A, 563, 53-59(2013).

[3] Mordike B L, Ebert T. Magnesium: properties-applications- potential[J]. Materials Science and Engineering: A, 302, 37-45(2001).

[4] Liu W J, Cao F H, Chen A N et al. Corrosion behaviour of AM60 magnesium alloys containing Ce or La under thin electrolyte layers. Part 1: microstructural characterization and electrochemical behaviour[J]. Corrosion Science, 52, 627-638(2010).

[5] Ignat S, Sallamand P, Grevey D et al. Magnesium alloys laser (Nd∶YAG) cladding and alloying with side injection of aluminium powder[J]. Applied Surface Science, 225, 124-134(2004).

[6] Vicenzi J, Marques C M, Bergmann C P. Hot and cold erosive wear of thermal sprayed NiCr-based coatings: influence of porosity and oxidation[J]. Surface and Coatings Technology, 202, 3688-3697(2008).

[7] Singh C, Tiwari S K, Singh R. Development of corrosion-resistant electroplating on AZ91 Mg alloy by employing air and water-stable eutectic based ionic liquid bath[J]. Surface and Coatings Technology, 428, 127881(2021).

[8] Liu Z M, Gao W. Electroless nickel plating on AZ91 Mg alloy substrate[J]. Surface and Coatings Technology, 200, 5087-5093(2006).

[9] Abela I S. 4-Physical vapour deposition on Mg alloys for biomedical applications[M]. Sankara N T S N, Park I S, Lee M H. Surface modification of magnesium and its alloys for biomedical applications, 81-100(2015).

[10] Alkhimov A P, Klinkov S V, Kosarev V F et al. Gas-dynamic spraying study of a plane supersonic two-phase jet[J]. Journal of Applied Mechanics and Technical Physics, 38, 324-330(1997).

[11] Assadi H, Gärtner F, Stoltenhoff T et al. Bonding mechanism in cold gas spraying[J]. Acta Materialia, 51, 4379-4394(2003).

[12] Grujicic M, Zhao C L, DeRosset W S et al. Adiabatic shear instability based mechanism for particles/substrate bonding in the cold-gas dynamic-spray process[J]. Materials & Design, 25, 681-688(2004).

[13] Alkhimov A P, Kosarev V F, Papyrin A N. Gas-dynamic spraying. An experimental study of the spraying process[J]. Journal of Applied Mechanics and Technical Physics, 39, 318-323(1998).

[14] Stoltenhoff T, Kreye H, Richter H J. An analysis of the cold spray process and its coatings[J]. Journal of Thermal Spray Technology, 11, 542-550(2002).

[15] Papyrin A. Cold spray technology[J]. Advanced Material & Process, 159, 49-51(2001).

[16] Jenkins R, Aldwell B, Yin S et al. Solid state additive manufacture of highly-reflective Al coatings using cold spray[J]. Optics & Laser Technology, 115, 251-256(2019).

[17] Marrocco T, Hussain T, McCartney D G et al. Corrosion performance of laser posttreated cold sprayed titanium coatings[J]. Journal of Thermal Spray Technology, 20, 909-917(2011).

[18] Sova A, Grigoriev S, Okunkova A et al. Cold spray deposition of 316L stainless steel coatings on aluminium surface with following laser post-treatment[J]. Surface and Coatings Technology, 235, 283-289(2013).

[19] Seng D H L, Zhang Z, Zhang Z Q et al. Influence of spray angle in cold spray deposition of Ti-6Al-4V coatings on Al6061-T6 substrates[J]. Surface and Coatings Technology, 432, 128068(2022).

[20] Song X, Ng K L, Chea J M K et al. Coupled Eulerian-Lagrangian (CEL) simulation of multiple particle impact during metal cold spray process for coating porosity prediction[J]. Surface and Coatings Technology, 385, 125433(2020).

[21] Wei Y K, Luo X T, Chu X et al. Solid-state additive manufacturing high performance aluminum alloy 6061 enabled by an in situ micro-forging assisted cold spray[J]. Materials Science and Engineering: A, 776, 139024(2020).

[22] Moridi A, Hassani-Gangaraj S M, Vezzú S et al. Fatigue behavior of cold spray coatings: the effect of conventional and severe shot peening as pre-/post-treatment[J]. Surface and Coatings Technology, 283, 247-254(2015).

[23] Kang N, Verdy C, Coddet P et al. Effects of laser remelting process on the microstructure, roughness and microhardness of in situ cold sprayed hypoeutectic Al-Si coating[J]. Surface and Coatings Technology, 318, 355-359(2017).

[24] Chen Z H, Sun X F, Li Z M et al. Effect of laser remelting on microstructure and properties of nickel aluminum bronze coating prepared by cold spraying[J]. Transactions of Materials and Heat Treatment, 38, 116-122(2017).

[25] Fairand B P, Clauer A H. Laser generated stress waves: their characteristics and their effects to materials[C], 50, 27-42(1979).

[26] Peyre P, Fabbro R, Merrien P et al. Laser shock processing of aluminium alloys. Application to high cycle fatigue behaviour[J]. Materials Science and Engineering: A, 210, 102-113(1996).

[27] Montross C S, Florea V, Bolger J A. Laser-induced shock wave generation and shock wave enhancement in basalt[J]. International Journal of Rock Mechanics and Mining Sciences, 36, 849-855(1999).

[28] Suhonen T, Varis T, Dosta S et al. Residual stress development in cold sprayed Al, Cu and Ti coatings[J]. Acta Materialia, 61, 6329-6337(2013).