AI Chat Paper
Note: Please note that the following content is generated by AMiner AI. SciOpen does not take any responsibility related to this content.
{{lang === 'zh_CN' ? '文章概述' : 'Summary'}}
{{lang === 'en_US' ? '中' : 'Eng'}}
Chat more with AI
Home Friction Article
PDF (4.2 MB)
Collect
Submit Manuscript AI Chat Paper
Show Outline
Outline
Show full outline
Hide outline
Outline
Show full outline
Hide outline
Short Communication | Open Access

Unlocking wear resistance in an ultrastrong dual-phase high-entropy alloy by interface-constrained deformation of brittle Laves phases

Fei LIANG1,Yixing SUN1,Hongyuan WAN2Yong LI1Wenhao LU1Ao MENG1Lei GU1Zhaoping LUO3Yan LIN1( )Yaping ZHANG1( )Xiang CHEN1( )
Nano and Heterogeneous Materials Center, School of Materials Science and Engineering, Nanjing University of Science and Technology, Nanjing 210094, China
Key Laboratory of Power Beam Processing, AVIC Manufacturing Technology Institute, Beijing 100024, China
Shenyang National Laboratory for Materials Science, Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016, China

† Fei LIANG and Yixing SUN contribute equally to this work.

Show Author Information

Graphical Abstract

Abstract

The pronounced brittleness of hard Laves phase intermetallics is detrimental to their tribological properties at room temperature. In this study, we utilized a heterogeneous structure to engineer an ultrastrong dual-phase (Laves + B2) AlCoFeNiNb high-entropy alloy that exhibits a low wear rate (3.82×10-6 mm3/(N·m)) at room temperature. This wear resistance in the ball-on-disc sliding friction test with the counterpart of Al2O3 balls stems from the activated deformation ability in the ultrafine Laves lamellae under heterogeneous interface constraints. Furthermore, as tribological stress intensifies, the surface deformation mechanism transitions from dislocation slip on the basal and pyramidal planes to a unique combination of local shear and grain rotation within the Laves phase. Our study illuminates fresh perspectives for mitigating the embrittling effect of Laves phase intermetallics under tribological loading and for the development of wear-resistant materials.

Electronic Supplementary Material

Download File(s)
friction-12-10-2389_ESM.pdf (3.4 MB)

References

[1]

Sui S, Tan H, Chen J, Zhong C, Li Z, Fan W, Gasser A, Huang W. The influence of Laves phases on the room temperature tensile properties of Inconel 718 fabricated by powder feeding laser additive manufacturing. Acta Mater 164: 413–427 (2019)

[2]

Yu Y, He F, Qiao Z, Wang Z, Liu W, Yang J. Effects of temperature and microstructure on the triblogical properties of CoCrFeNiNbx eutectic high entropy alloys. J Alloy Compd 775: 1376–1385 (2019)

[3]

Chisholm M F, Kumar S, Hazzledine P. Dislocations in complex materials. Science 307: 701–703 (2005)

[4]

Zhang W, Yu R, Du K, Cheng Z, Zhu J, Ye H. Undulating slip in Laves phase and implications for deformation in brittle materials. Phys Rev Lett 106: 165505 (2011)

[5]

Takata N, Ghassemi Armaki H, Terada Y, Takeyama M, Kumar K S. Plastic deformation of the C14 Laves phase (Fe,Ni)2Nb. Scripta Mater 68: 615–618 (2013)

[6]

Scudino S, Donnadieu P, Surreddi K B, Nikolowski K, Stoica M, Eckert J. Microstructure and mechanical properties of Laves phase-reinforced Fe–Zr–Cr alloys. Intermetallics 17: 532–539 (2009)

[7]

Rabadia C D, Liu Y J, Chen L Y, Jawed S F, Wang L Q, Sun H, Zhang L C. Deformation and strength characteristics of Laves phases in titanium alloys. Mater Design 179: 107891 (2019)

[8]

Padilla H A, Boyce B L, Battaile C C, Prasad S V. Frictional performance and near-surface evolution of nanocrystalline Ni–Fe as governed by contact stress and sliding velocity. Wear 297: 860–871 (2013)

[9]

An X L, Liu Z D, Zhang L T, Zou Y, Xu X J, Chu C L, Wei W, Sun W W. A new strong pearlitic multi-principal element alloy to withstand wear at elevated temperatures. Acta Mater 227: 117700 (2022)

[10]

Chen X, Han Z, Li X Y, Lu K. Lowering coefficient of friction in Cu alloys with stable gradient nanostructures. Sci Adv 2: e1601942 (2016)

[11]

Liang F, Meng A, Sun Y, Chen Z, Jiang Z, Zhang Y, Zhang Y, Zhu Y, Chen X. A novel wear-resistant Ni-based superalloy via high Cr-induced subsurface nanotwins and heterogeneous composite glaze layer at elevated temperatures. Tribol Int 183: 108383 (2023)

[12]

Liu C, Li Z, Lu W, Bao Y, Xia W, Wu X, Zhao H, Gault B, Liu C, Herbig M, Fischer A, Dehm G, Wu G, Raabe D. Reactive wear protection through strong and deformable oxide nanocomposite surfaces. Nat Commun 12: 5518 (2021)

[13]

Yang W, Luo J, Fu H, Cheung C F, Ruan H, Yang X. bcc → hcp phase transition significantly enhancing the wear resistance of metastable refractory high-entropy alloy. Scripta Mater 221: 114966 (2022)

[14]

Zhou Q, Luo D, Ye W, Li S, Huang Z, Ma B, Wang H. Mechanical and tribological behaviors of metallic glass/graphene film with a laminated structure. Compos Part A 155: 106851 (2022)

[15]

Ren Y, Jia Q, Du Y, Zhou Q, Greiner C, Hua K, Wang H, Wang J. A wear-resistant metastable CoCrNiCu high-entropy alloy with modulated surface and subsurface structures. Friction 10: 1722–1738 (2022)

[16]

Lou M, Chang K, Xu K, Chen L, Lv J, Du Y, Chen X, Wang L. Achieving exceptional wear resistance in cemented carbides using B2 intermetallic binders, Compos Part B 249: 110400 (2023)

[17]

Ayyagari A, Barthelemy C, Gwalani B, Banerjee R, Scharf T W, Mukherjee S. Reciprocating sliding wear behavior of high entropy alloys in dry and marine environments. Mater Chem Phys 210: 162–169 (2018)

[18]

Chen M, Lan L, Shi X, Yang H, Zhang M, Qiao J. The tribological properties of Al0.6CoCrFeNi high-entropy alloy with the σ phase precipitation at elevated temperature. J Alloy Compd 777: 180–189 (2019)

[19]

Chen M, Shi X H, Yang H, Liaw P K, Gao M C, Hawk J A, Qiao J. Wear behavior of Al0.6CoCrFeNi high-entropy alloys: Effect of environments. J Mater Res 33: 3310–3320 (2018)

[20]

Chen X, Kong J, Li J, Feng S, Li H, Wang Q, Liang Y, Dong K, Yang Y. High-strength AlCoCrFeNi2.1 eutectic high entropy alloy with ultrafine lamella structure via additive manufacturing. Mater Sci Eng A 854: 143816 (2022)

[21]

Cheng H, Fang Y, Xu J, Zhu C, Dai P, Xue S. Tribological properties of nano/ultrafine-grained FeCoCrNiMnAlx high-entropy alloys over a wide range of temperatures. J Alloy Compd 817: 153305 (2020)

[22]

Deng G, Tieu A K, Su L, Wang P, Wang L, Lan X, Cui S, Zhu H. Investigation into reciprocating dry sliding friction and wear properties of bulk CoCrFeNiMo high entropy alloys fabricated by spark plasma sintering and subsequent cold rolling processes: Role of Mo element concentration. Wear 460–461: 203440 (2020)

[23]

Dong J, Wu H, Chen Y, Zhang Y, Wu Y, Yin S, Du Y, Hua K, Wang H. Study on self-lubricating properties of AlCoCrFeNi2.1 eutectic high entropy alloy with electrochemical boronizing. Surf Coat Technol 433: 128082 (2022)

[24]

Doni Z, Alves A C, Toptan F, Gomes J R, Ramalho A, Buciumeanu M, Palaghian L, Silva F S. Dry sliding and tribocorrosion behaviour of hot pressed CoCrMo biomedical alloy as compared with the cast CoCrMo and Ti6Al4V alloys. Mater Des 52: 47–57 (2022)

[25]

Du L M, Lan L W, Zhu S, Yang H J, Shi X H, Liaw P K, Qiao J W. Effects of temperature on the tribological behavior of Al0.25CoCrFeNi high-entropy alloy. J Mater Sci Technol 35: 917–925 (2019)

[26]

Gwalani B, Ayyagari A V, Choudhuri D, Scharf T, Mukherjee S, Gibson M, Banerjee R. Microstructure and wear resistance of an intermetallic-based Al0.25Ti0.75CoCrFeNi high entropy alloy. Mater Chem Phys 210: 197–206 (2018)

[27]

Huang C, Zhang Y, Vilar R, Shen J. Dry sliding wear behavior of laser clad TiVCrAlSi high entropy alloy coatings on Ti–6Al–4V substrate. Mater Des 41: 338–343 (2012)

[28]

Joseph J, Haghdadi N, Shamlaye K, Hodgson P, Barnett M, Fabijanic D. The sliding wear behaviour of CoCrFeMnNi and AlxCoCrFeNi high entropy alloys at elevated temperatures. Wear 428–429: 32–44 (2019)

[29]

Liu Y, Ma S, Gao M C, Zhang C, Zhang T, Yang H, Wang Z, Qiao J. Tribological properties of AlCrCuFeNi2 high-entropy alloy in different conditions. Metall Mater Trans A 47: 3312–3321 (2016)

[30]

Miao J, Guo T, Ren J, Zhang A, Su B, Meng J. Optimization of mechanical and tribological properties of FCC CrCoNi multi-principal element alloy with Mo addition. Vacuum 149: 324–330 (2018)

[31]

Pan S, Zhao C, Wei P, Ren F. Sliding wear of CoCrNi medium-entropy alloy at elevated temperatures: Wear mechanism transition and subsurface microstructure evolution. Wear 440–441: 203108 (2019)

[32]

Wang Y, Yang Y, Yang H, Zhang M, Ma S, Qiao J. Microstructure and wear properties of nitrided AlCoCrFeNi high-entropy alloy. Mater Chem Phys 210: 233–239 (2018)

[33]

Wang Y, Yang Y, Yang H, Zhang M, Qiao J. Effect of nitriding on the tribological properties of Al1.3CoCuFeNi2 high-entropy alloy. J Alloy Compd 725: 365–372 (2017)

[34]

Yadav S, Aggrawal A, Kumar A, Biswas K. Effect of TiB2 addition on wear behavior of (AlCrFeMnV)90Bi10 high entropy alloy composite. Tribol Int 132: 62–74 (2019)

[35]

Zhang A, Han J, Su B, Li P, Meng J. Microstructure, mechanical properties and tribological performance of CoCrFeNi high entropy alloy matrix self-lubricating composite. Mater Des 114: 253–263 (2017)

[36]

Zhang A, Han J, Su B, Meng J. A novel CoCrFeNi high entropy alloy matrix self-lubricating composite. J Alloy Compd 725: 700–710 (2017)

[37]

Zhang A, Han J, Su B, Meng J. A promising new high temperature self-lubricating material: CoCrFeNiS0.5 high entropy alloy. Mater Sci Eng A 731: 36–43 (2018)

[38]

Leyland A, Matthews A. On the significance of the H/E ratio in wear control: A nanocomposite coating approach to optimised tribological behaviour. Wear 246: 1–11 (2000)

[39]

Meng Y, Xu J, Ma L, Jin Z, Prakash B, Ma T, Wang W. A review of advances in tribology in 2020–2021. Friction 10: 1443–1595 (2022)

[40]

Chen L, Zhang Z, Lou M, Xu K, Wang L, Meng F, Music D, Chang K. High-temperature wear mechanisms of TiNbWN films: Role of nanocrystalline oxides formation. Friction 11: 460–472 (2022)

[41]

Wang Y, Zhao X, Hao E, Bu Z, An Y, Zhou H, Chen J. High temperature induced “glaze” layer formed in HVOF-sprayed NiCrWMoCuCBFe coating and its wear reduction mechanism. Friction 10: 1424–1438 (2022)

[42]

Haug C, Ruebeling F, Kashiwar A, Gumbsch P, Kübel C, Greiner C. Early deformation mechanisms in the shear affected region underneath a copper sliding contact. Nat Commun 11: 839 (2020)

[43]

Zhu Y, Ameyama K, Anderson P M, Beyerlein I J, Gao H, Kim H S, Lavernia E, Mathaudhu S, Mughrabi H, Ritchie R O, Tsuji N, Zhang X, Wu X. Heterostructured materials: Superior properties from hetero-zone interaction. Mater Res Lett 9: 1–31 (2021)

[44]

Shi P, Li R, Li Y, Wen Y, Zhong Y, Ren W, Shen Z, Zheng T, Peng J, Liang X, Hu P, Min N, Zhang Y, Ren Y, Liaw P K, Raabe D, Wang Y D. Hierarchical crack buffering triples ductility in eutectic herringbone high-entropy alloys. Science 373: 912–918 (2021)

[45]

Ren J, Zhang Y, Zhao D, Chen Y, Guan S, Liu Y, Liu L, Peng S, Kong F, Poplawsky J D, Gao G, Voisin T, An K, Wang Y M, Xie K Y, Zhu T, Chen W. Strong yet ductile nanolamellar high-entropy alloys by additive manufacturing. Nature 608: 62–68 (2022)

[46]

Huang C X, Wang Y F, Ma X L, Yin S, Hoppel H W, Goken M, Wu X L, Gao H J, Zhu Y T. Interface affected zone for optimal strength and ductility in heterogeneous laminate. Mater Today 21: 713–719 (2018)

[47]

Gu L, Liang N, Liu Y, Chen Y, Liu J, Sun Y, Zhao Y. Novel as-cast NiAlCoFeNb dual-phase high-entropy alloys with high hardness. Mater Lett 324: 132676 (2022)

[48]

Zhu W, Zhao C, Zhang Y, Kwok C T, Luan J, Jiao Z, Ren F. Achieving exceptional wear resistance in a compositionally complex alloy via tuning the interfacial structure and chemistry. Acta Mater 188: 697–710 (2020)

[49]

Chen Y, Wu H, Dong J, Yin S, Hua K, Wang H. Surface strengthening and self-lubrication enhancement of CoCrNi medium-entropy alloy by powder-pack boronizing. Wear 500–501: 204353 (2022)

[50]

Beets N, Cui Y C, Farkas D, Misra A. Mechanical response of a bicontinuous copper-molybdenum nanocomposite: Experiments and simulations. Acta Mater 178: 79–89 (2019)

[51]

Wei K, Hu R, Yin D, Xiao L, Pang S, Cao Y, Zhou H, Zhao Y, Zhu Y. Grain size effect on tensile properties and slip systems of pure magnesium. Acta Mater 206: 116604 (2021)

Friction
Pages 2389-2398
Cite this article:
LIANG F, SUN Y, WAN H, et al. Unlocking wear resistance in an ultrastrong dual-phase high-entropy alloy by interface-constrained deformation of brittle Laves phases. Friction, 2024, 12(10): 2389-2398. https://doi.org/10.1007/s40544-024-0884-5

184

Views

8

Downloads

0

Crossref

0

Web of Science

0

Scopus

0

CSCD

Altmetrics

Received: 04 August 2023
Revised: 02 November 2023
Accepted: 06 February 2024
Published: 05 July 2024
© The author(s) 2024.

This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made.

The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder.

To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.

Return