Laser Surface Micro-texturing of Zr-based Bulk Metallic Glass and Investigation of Tribological and Wear Performance

doi:10.12068/j.issn.1005-3026.2022.11.008

Abstract

Abstract: A nanosecond laser-based surface texturing technique，which combined laser surface texturing and low-temperature heat treatment， was developed to functionalize the metallic glass surface. Firstly， laser surface texturing within a specific processing window was utilized to create periodic surface structures on the Zr-based metallic glass， and subsequently heat treatment was employed to control the surface energy/chemistry of the laser textured metallic glass. The experimental results indicated that the laser textured and heat-treated metallic glass surface exhibits changes for both surface structure and surface chemistry， and realizes the wettability transition from superhydrophilicity to superhydrophobicity. In the meantime， the friction test results indicated that the laser textured superhydrophobic surface effectively improves the anti-friction performance with the help of lubrication medium.

Key words: laser processing; metallic glass; superwetting surface; micro/nanostructure; tribological and wear performance

CLC Number:

TN249

WANG Qing-hua， CHENG Yang-yang， WANG Hui-xin. Laser Surface Micro-texturing of Zr-based Bulk Metallic Glass and Investigation of Tribological and Wear Performance[J]. Journal of Northeastern University(Natural Science), 2022, 43(11): 1575-1582.

References

[1]Miller M，Liaw P.Bulk metallic glasses:an overview［M］.Boston:Springer，2008.
[2]Lffler J F.Bulk metallic glasses［J］.Intermetallics，2003，11:529-540.
[3]Telford M.The case for bulk metallic glass［J］.Materials Today，2004，7:36-43.
[4]Bian Z，Chen G L，He G，et al.Microstructure and ductile-brittle transition of as-cast Zr-based bulk glass alloys under compressive testing［J］.Materials Science and Engineering A，2001，A316:135-144.
[5]Huang H，Yan J.Investigating shear band interaction in metallic glasses by adjacent nanoindentation［J］.Materials Science and Engineering A，2017，A704:375-385.
[6]Liu W，Zhang H，Shi J A，et al.A room-temperature magnetic semiconductor from a ferromagnetic metallic glass［J］.Nature Communications，2016，7:13497.
[7]Li H F，Zheng Y F.Recent advances in bulk metallic glasses for biomedical applications［J］.Acta Biomaterialia，2016，36:1-20.
[8]Khan M M，Nemati A，Rahman Z U，et al.Recent advancements in bulk metallic glasses and their applications:a review［J］.Critical Reviews in Solid State and Materials Sciences，2018，43(3):233-268.
[9]Hirano T，Kato H，Matsuo A，et al.Synthesis and mechanical properties of Zr55Al10Ni5Cu30 bulk glass composites containing ZrC particles formed by the in-situ reaction［J］.Materials Transactions，JIM，2000，41(11):1454-1459.
[10]Kumar G，Tang H X，Schroers J.Nanomoulding with amorphous metals［J］.Nature，2009，457:868-872.
[11]Hu Z，Gorumlu S，Aksak B，et al.Patterning of metallic glasses using polymer templates［J］.Scripta Materialia，2015，108:15-18.
[12]He P，Li L，Wang F，et al.Bulk metallic glass mold for high volume fabrication of micro optics［J］.Microsystem Technologies，2016，22:617-623.
[13]Chen N，Frank R，Asao N，et al.Formation and properties of Au-based nanograined metallic glasses［J］.Acta Materialia，2011，59:6433-6440.
[14]Ketov S V，Shi X，Xie G，et al.Nanostructured Zr-Pd metallic glass thin film for biochemical applications［J］.Scientific Reports，2015，5:7799.
[15]Zhao M，Abe K，Yamaura S，et al.Fabrication of Pd-Ni-P metallic glass nanoparticles and their application as highly durable catalysts in Methanol electro-oxidation［J］.Chemistry of Materials，2014，26:1056-1061.
[16]Bakkal M，Shih A J，Scattergood R O，et al.Machining of a Zr-Ti-Al-Cu-Ni metallic glass［J］.Scripta Materialia，2004，50:583-588.
[17]Zhang X，Zhang Y，Tong H，et al.Micro-electro-discharge machining of bulk metallic glasses［C］//Proceedings of International Symposium on High Density Packaging and Microsystem Integration 2007.Shanghai，2007:30-33.
[18]Sawyer V，Tao X，Dong H，et al.Improving the tribological properties and biocompatibility of Zr-based bulk metallic glass for potential biomedical applications［J］.Materials，2020，13:1960.
[19]Vorobyev A Y，Guo C.Multifunctional surfaces produced by femtosecond laser pulses［J］.Journal of Applied Physics，2015，117(3):1033-1040.
[20]Liu B，Jiang G，Wang W，et al.Porous microstructures induced by picosecond laser scanning irradiation on stainless steel surface［J］.Optics and Lasers in Engineering，2016，78:55-63.
[21]Long J，Fan P，Gong D，et al.Superhydrophobic surfaces fabricated by femtosecond laser with tunable water adhesion:from lotus leaf to rose petal［J］.ACS Applied Materials and Interfaces，2015，7(18):9858-9865.
[22]Long J，Zhong M，Zhang H，et al.Superhydrophilicity to superhydrophobicity transition of picosecond laser microstructured aluminum in ambient air［J］.Journal of Colloid and Interface Science，2015，441:1-9.
[23]Long J，Fan P，Zhong M，et al.Superhydrophobic and colorful copper surfaces fabricated by picosecond laser induced periodic nanostructures［J］.Applied Surface Science，2014，311:461-467.
[24]Chen F，Zhang D，Yang Q，et al.Bioinspired wetting surface via laser microfabrication［J］.ACS Applied Materials and Interfaces，2013，5(15):6777-6792.
[25]Huang H，Jun N，Jiang M，et al.Nanosecond pulsed laser irradiation induced hierarchical micro/nanostructures on Zr-based metallic glass substrate［J］.Materials and Design，2016，109:153-161.
[26]Jiao Y，Brousseau E，Han Q，et al.Investigations in nanosecond laser micromachining on the Zr52.8Cu17.6Ni14.8Al9.9Ti4.9 bulk metallic glass:experimental and theoretical study［J］.Journal of Materials Processing Technology，2019，273:116232.
[27]Jiao Y，Brousseau E，Shen X，et al.Investigations in the fabrication of surface patterns for wettability modification on a Zr-based bulk metallic glass by nanosecond laser surface texturing［J］.Journal of Materials Processing Technology，2020，283:116714.
[28]Jiao Y，Brousseau E，Nishio A W，et al.In vitro cyto compatibility of a Zr-based metallic glass modified by laser surface texturing for potential implant applications［J］.Applied Surface Science，2021，547:149194.
[29]Du C，Wang C，Zhang T，et al.Reduced bacterial adhesion on zirconium-based bulk metallic glasses by femtosecond laser nanostructuring［J］.Proceedings of the Institution of Mechanical Engineers，Part H:Journal of Engineering in Medicine，2020，234(4):387-397.
[30]姚燕生，唐建平，张亚超，等.非晶合金激光制造技术研究进展［J］.中国激光，2021，48(2):0202012.(Yao Yan-sheng，Tang Jian-ping，Zhang Ya-chao，et al.Development of laser fabrication technology for amorphous alloys［J］.Chinese Journal of Lasers，2021，48(2):0202012.)［31］Madge S V.Toughness of bulk metallic glasses［J］.Metals，2015，5:1279-1305.［32］Jafary-Zadeh M，Kumar G P，Branicio P S，et al.A critical review on metallic glasses as structural materials for cardiovascular stent applications［J］.Journal of Functional Biomaterials，2018，9:19.［33］Wu H，Liang L，Lan X，et al.Tribological and biological behaviors of laser cladded Ti-based metallic glass composite coatings［J］.Applied Surface Science，2020，507:145104.［34］Lan X，Wu H，Liu Y，et al.Microstructures and tribological properties of laser cladded Ti-based metallic glass composite coatings［J］.Materials Characterization，2016，120:82-89.［35］Qian Y，Jiang M，Zhang Z，et al.On the transformation between micro-concave and micro-convex in nanosecond laser ablation of a Zr-based metallic glass［J］.Journal of Manufacturing Processes，2021，68:1114-1122.［36］Zhang H，Qian Y，Zhang L，et al.Surface coloration of Zr-based metallic glass by nanosecond pulsed laser irradiation in ambient atmosphere［J］.Materials Letters，2021，304:130721.［37］姚燕生，葛张森，陈庆波，等.医用锆基块体非晶合金飞秒激光加工表面特性研究［J］.激光与光电子学进展，2020，57(11):111409.(Yao Yan-sheng，Ge Zhang-sen，Chen Qing-bo，et al.Surface characteristics of medical Zr-based bulk metallic glass processed by femtosecond laser［J］.Laser & Optoelectronics Progress， 2020，57(11):111409.)［38］Gregorcˇicˇ P.Comment on “Bioinspired reversible switch between underwater superoleophobicity/superaerophobicity and oleophilicity/aerophilicity and improved antireflective property on the nanosecond laser-ablated superhydrophobic titanium surfaces”［J］.ACS Applied Materials and Interfaces，2021，13(2):2117-2127.［39］马国峰.非晶态合金及表面润湿性［M］.沈阳:东北大学出版社，2010.(Ma Guo-feng.Metallic glass and wettability of surface［M］.Shenyang:Northeastern University Press，2010.)［40］Gregorcˇicˇ P，etina-Baticˇ B，Hocˇevar M，et al.Controlling the stainless steel surface wettability by nanosecond direct laser texturing at high fluences［J］.Applied Physics A:Materials Science and Processing，2017，123(12):766.［41］Wang Q H，Wang H X，Zhu Z X，et al.Switchable wettability control of titanium via facile nanosecond laser-based surface texturing［J］.Surfaces and Interfaces，2021，24:101122.［42］Wang Q H，Cheng Y Y，Zhu Z X，et al.Modulation and control of wettability and hardness of Zr-based metallic glass via facile laser surface texturing［J］.Micromachines，2021，12(11):1322.［43］Borruto A，Crivellone G，Marani F.Influence of surface wettability on friction and wear tests［J］.Wear，1998，222(1):57-65.