New trends in additive manufacturing of high-entropy alloys and alloy design by machine learning: from single-phase to multiphase systems

Yinghao Zhou , Zehuan Zhang , Dawei Wang , Weicheng Xiao , Jiang Ju , Shaofei Liu , Bo Xiao , Ming Yan , Tao Yang

Journal of Materials Informatics ›› 2022, Vol. 2 ›› Issue (4) : 18

PDF
Journal of Materials Informatics ›› 2022, Vol. 2 ›› Issue (4) :18 DOI: 10.20517/jmi.2022.27
Review

New trends in additive manufacturing of high-entropy alloys and alloy design by machine learning: from single-phase to multiphase systems

Author information +
History +
PDF

Abstract

Alloys with excellent properties are always in significant demand for meeting the severe conditions of industrial applications. However, the design strategies of traditional alloys based on a single principal element have reached their limits in terms of property optimization. The concept of high-entropy alloys (HEAs) provides a new design strategy based on multicomponent elements, which may overcome the bottleneck problems that exist in traditional alloys. To further maximize the capability of HEAs, a novel additive manufacturing (AM) technique has been utilized to produce HEA components with the desired structures and properties. This review considers a new trend in the AM of HEAs, i.e., from the AM of single-phase HEAs to multiphase HEAs. Although most as-printed single-phase HEAs show superior tensile properties to as-cast ones, their strength is still not satisfactory, especially at elevated temperatures. Thus, multiphase HEAs are developed by introducing hard second phases, such as L12, BCC, carbides, oxides, nitrides, and so on. These phases can be introduced to the matrix using in situ alloying during AM or the subsequent heat treatment. Dislocation strengthening is considered as the main reason for improving the tensile properties of as-printed single-phase HEAs. In contrast, multiple strengthening and toughening mechanisms occur in as-printed multiphase HEAs, which can synergistically enhance their mechanical properties. Furthermore, machine learning provides an effective method to design new alloys with the desired properties and predict the optimal AM parameters for the designed alloys without tedious experiments. The synergistic combination of machine learning and AM will significantly speed up scientific advances and promote industrial applications.

Keywords

High-entropy alloys / additive manufacturing / precipitation hardening / strengthening mechanism / machine learning

Cite this article

Download citation ▾
Yinghao Zhou, Zehuan Zhang, Dawei Wang, Weicheng Xiao, Jiang Ju, Shaofei Liu, Bo Xiao, Ming Yan, Tao Yang. New trends in additive manufacturing of high-entropy alloys and alloy design by machine learning: from single-phase to multiphase systems. Journal of Materials Informatics, 2022, 2(4): 18 DOI:10.20517/jmi.2022.27

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Yeh JW,Lin SJ et al.Nanostructured high-entropy alloys with multiple principal elements: novel alloy design concepts and outcomes.Adv Eng Mater2004;6:299-303

[2]

Cantor B,Knight P.Microstructural development in equiatomic multicomponent alloys.Mater Sci Eng A2004;375:213-8

[3]

Ritchie RO.Growing designability in structural materials.Nat Mater2022;21:968-70

[4]

Ye Y,Lu J,Yang Y.High-entropy alloy: challenges and prospects.Mater Today2016;19:349-62

[5]

Zhao Y,Ma S et al.A hexagonal close-packed high-entropy alloy: the effect of entropy.Mater Des2016;96:10-5

[6]

Yang T,Tong Y.Multicomponent intermetallic nanoparticles and superb mechanical behaviors of complex alloys.Science2018;362:933-7

[7]

Lu Y,Guo S et al.A promising new class of high-temperature alloys: eutectic high-entropy alloys.Sci Rep2014;4:1-5 PMCID:PMC4145285
[8]

He F,Cheng P et al.Designing eutectic high entropy alloys of CoCrFeNiNbx.J Alloys Compd2016;656:284-9

[9]

Kuznetsov AV,Stepanov ND,Senkov ON.Tensile properties of an AlCrCuNiFeCo high-entropy alloy in as-cast and wrought conditions.Mater Sci Eng A2012;533:107-18

[10]

Takeuchi A,Wada T,Zhang W.High-entropy alloys with a hexagonal close-packed structure designed by equi-atomic alloy strategy and binary phase diagrams.JOM2014;66:1984-92

[11]

Yu P,Ning J et al.Pressure-induced phase transitions in HoDyYGdTb high-entropy alloy.Mater Lett2017;196:137-40

[12]

Zhang Y,Tang Z et al.Microstructures and properties of high-entropy alloys.Prog Mater Sci2014;61:1-93

[13]

Guo L,Ni S,Song M.Effects of carbon on the microstructures and mechanical properties of FeCoCrNiMn high entropy alloys.Mater Sci Eng A2019;746:356-62

[14]

Cheng H,Xie Y,Dai P.Controllable fabrication of a carbide-containing FeCoCrNiMn high-entropy alloy: microstructure and mechanical properties.Mater Sci Technol2017;33:2032-9

[15]

Zheng M,Zhang X,Yang X.The influence of columnar to equiaxed transition on deformation behavior of FeCoCrNiMn high entropy alloy fabricated by laser-based directed energy deposition.Addit Manuf2021;37:101660

[16]

Gali A.Tensile properties of high-and medium-entropy alloys.Intermetallics2013;39:74-8

[17]

Liu B,Liu Y et al.Microstructure and mechanical properties of equimolar FeCoCrNi high entropy alloy prepared via powder extrusion.Intermetallics2016;75:25-30

[18]

Lin D,Han Y et al.Structure and mechanical properties of a FeCoCrNi high-entropy alloy fabricated via selective laser melting.Intermetallics2020;127:106963

[19]

Peng Y,Song L et al.The manufacturing process optimization and the mechanical properties of FeCoCrNi high entropy alloys fabricated by selective laser melting.Intermetallics2022;145:107557

[20]

Lin D,Jing H,Zhao L.Effects of annealing on the structure and mechanical properties of FeCoCrNi high-entropy alloy fabricated via selective laser melting.Addit Manuf2020;32:101058

[21]

Xiong F,Li Y,Qi X.Influences of nitrogen alloying on microstructural evolution and tensile properties of CoCrFeMnNi high-entropy alloy treated by cold-rolling and subsequent annealing.Mater Sci Eng A2020;787:139472

[22]

He J,Wang H et al.Effects of Al addition on structural evolution and tensile properties of the FeCoNiCrMn high-entropy alloy system.Acta Mater2014;62:105-13

[23]

Yan X,Yang W et al.Al0.3CrxFeCoNi high-entropy alloys with high corrosion resistance and good mechanical properties.J Alloys Compd2021;860:158436

[24]

Zhang J,Zhu H.Effect of Al additions on the microstructures and tensile properties of AlxCoCr3Fe5Ni high entropy alloys.Mater Charact2021;175:111091

[25]

Jin X,Zhang L,Zhou Y.Back stress strengthening dual-phase AlCoCr2FeNi2 high entropy alloy with outstanding tensile properties.Mater Sci Eng A2019;745:137-43

[26]

Jin X,Zhang L,Li B.A novel Fe20Co20Ni41Al19 eutectic high entropy alloy with excellent tensile properties.Mater Lett2018;216:144-6

[27]

Bhattacharjee T,Chong Y et al.Effect of low temperature on tensile properties of AlCoCrFeNi2.1 eutectic high entropy alloy.Mater Chem Phys2018;210:207-12

[28]

Chen X,Zhu J et al.Influences of Ti additions on the microstructure and tensile properties of AlCoCrFeNi2.1 eutectic high entropy alloy.Intermetallics2021;128:107024

[29]

Vo TD,Tieu AK,Deng G.Effects of oxidation on friction and wear properties of eutectic high-entropy alloy AlCoCrFeNi2.1.Tribol Int2021;160:107017

[30]

Yu Y,Qiao Z,Liu W.Effects of temperature and microstructure on the triblogical properties of CoCrFeNiNbx eutectic high entropy alloys.J Alloys Compd2019;775:1376-85

[31]

Wu Y,Wang T et al.A refractory Hf25Nb25Ti25Zr25 high-entropy alloy with excellent structural stability and tensile properties.Mater Lett2014;130:277-80

[32]

Lilensten L,Bourgon J et al.Design and tensile properties of a BCC Ti-rich high-entropy alloy with transformation-induced plasticity.Mater Res Lett2017;5:110-6

[33]

Wang S,Shu D,Wang D.Mechanical instability and tensile properties of TiZrHfNbTa high entropy alloy at cryogenic temperatures.Acta Mater2020;201:517-27

[34]

Huang H,Cao P et al.On cooling rates dependence of microstructure and mechanical properties of refractory high-entropy alloys HfTaTiZr and HfNbTiZr.Scr Mater2022;211:114506

[35]

Chen Y,Wang M,Wu C.A single-phase V0.5Nb0.5ZrTi refractory high-entropy alloy with outstanding tensile properties.Mater Sci Eng A2020;792:139774

[36]

Senkov O,Semiatin S.Effect of cold deformation and annealing on the microstructure and tensile properties of a HfNbTaTiZr refractory high entropy alloy.Metall Mater Trans A2018;49:2876-92

[37]

Juan C-C,Tsai C-W et al.Simultaneously increasing the strength and ductility of a refractory high-entropy alloy via grain refining.Mater Lett2016;184:200-3

[38]

Zhao Y,Tong Y et al.Heterogeneous precipitation behavior and stacking-fault-mediated deformation in a CoCrNi-based medium-entropy alloy.Acta Mater2017;138:72-82

[39]

Du X,Chang H et al.Dual heterogeneous structures lead to ultrahigh strength and uniform ductility in a Co-Cr-Ni medium-entropy alloy.Nat Commun2020;11:1-7 PMCID:PMC7220923
[40]

Zhao Y,Zhu J et al.Development of high-strength Co-free high-entropy alloys hardened by nanosized precipitates.Scr Mater2018;148:51-5

[41]

Fan L,Zhao Y et al.Ultrahigh strength and ductility in newly developed materials with coherent nanolamellar architectures.Nat Commun2020;11:1-8 PMCID:PMC7721903
[42]

Yang T,Luan J et al.Nanoparticles-strengthened high-entropy alloys for cryogenic applications showing an exceptional strength-ductility synergy.Scr Mater2019;164:30-5

[43]

Zhao Y,Li Y et al.Superior high-temperature properties and deformation-induced planar faults in a novel L12-strengthened high-entropy alloy.Acta Mater2020;188:517-27

[44]

He F,Liu S et al.Strain partitioning enables excellent tensile ductility in precipitated heterogeneous high-entropy alloys with gigapascal yield strength.Int J Plast2021;144:103022

[45]

He J,Huang H et al.A precipitation-hardened high-entropy alloy with outstanding tensile properties.Acta Mater2016;102:187-96

[46]

Wang Z,Fu L et al.Effect of coherent L12 nanoprecipitates on the tensile behavior of a fcc-based high-entropy alloy.Mater Sci Eng A2017;696:503-10

[47]

Zhao Y,Yeli G et al.Anomalous precipitate-size-dependent ductility in multicomponent high-entropy alloys with dense nanoscale precipitates.Acta Mater2022;223:117480

[48]

Liu W,He J et al.Ductile CoCrFeNiMox high entropy alloys strengthened by hard intermetallic phases.Acta Mater2016;116:332-42

[49]

Xiao B,Zhao S et al.Achieving thermally stable nanoparticles in chemically complex alloys via controllable sluggish lattice diffusion.Nat Commun2022;13:1-8 PMCID:PMC9388539
[50]

Anderson IE,Dehoff R.Feedstock powder processing research needs for additive manufacturing development.Curr Opin Solid State Mater Sci2018;22:8-15

[51]

Zhang Z,Zhou S,Yan M.Mechanically blended Al: simple but effective approach to improving mechanical property and thermal stability of selective laser-melted Inconel 718.Metall Mater Trans A2019;50:3922-36

[52]

Zhang T,Yang T.In situ design of advanced titanium alloy with concentration modulations by additive manufacturing.Science2021;374:478-82

[53]

Bikas H,Chryssolouris G.Additive manufacturing methods and modelling approaches: a critical review.Int J Adv Manuf Technol2016;83:389-405

[54]

Singh DD,Reddy AR.Functionally graded materials manufactured by direct energy deposition: a review.Mater Today: Proc2021;47:2450-6

[55]

Perrin AE.Stabilized nanocrystalline alloys: the intersection of grain boundary segregation with processing science.Annu Rev Mater Res2021;51:241-68

[56]

Zhu Y,Meng Z et al.Ultrastrong nanotwinned titanium alloys through additive manufacturing.Nat Mater2021;21:1258-62

[57]

Frazier WE.Metal additive manufacturing: a review.J Mater Eng Perform2014;23:1917-28

[58]

Li M-X,Wang C et al.Data-driven discovery of a universal indicator for metallic glass forming ability.Nat Mater2022;21:165-72

[59]

Zhu Z,Ng F et al.Hierarchical microstructure and strengthening mechanisms of a CoCrFeNiMn high entropy alloy additively manufactured by selective laser melting.Scr Mater2018;154:20-4

[60]

Li R,Yuan T,Chen C.Selective laser melting of an equiatomic CoCrFeMnNi high-entropy alloy: processability, non-equilibrium microstructure and mechanical property.J Alloys Compd2018;746:125-34

[61]

Guo L,Gan B et al.Effects of elemental segregation and scanning strategy on the mechanical properties and hot cracking of a selective laser melted FeCoCrNiMn-(N, Si) high entropy alloy.J Alloys Compd2021;865:158892

[62]

Zhang C,Kokawa H,Li Z.Cracking mechanism and mechanical properties of selective laser melted CoCrFeMnNi high entropy alloy using different scanning strategies.Mater Sci Eng A2020;789:139672

[63]

Lin D,Li X et al.High-temperature mechanical properties of FeCoCrNi high-entropy alloys fabricated via selective laser melting.Mater Sci Eng A2022;832:142354

[64]

Brif Y,Todd I.The use of high-entropy alloys in additive manufacturing.Scr Mater2015;99:93-6

[65]

Zhou P,Wu Z.Al0.5FeCoCrNi high entropy alloy prepared by selective laser melting with gas-atomized pre-alloy powders.Mater Sci Eng A2019;739:86-9

[66]

Xu J,Feng K et al.Enhanced strength and ductility of laser powder bed fused NbMoTaW refractory high-entropy alloy via carbon microalloying.Addit Manuf Lett2022;3:100079

[67]

Zhang H,Cai J et al.High-strength NbMoTaX refractory high-entropy alloy with low stacking fault energy eutectic phase via laser additive manufacturing.Mater Des2021;201:109462

[68]

Yang F,Wang Z et al.Ultra strong and ductile eutectic high entropy alloy fabricated by selective laser melting.J Mater Sci Technol2022;106:128-32

[69]

He L,Dong A et al.Selective laser melting of dense and crack-free AlCoCrFeNi2.1 eutectic high entropy alloy: synergizing strength and ductility.J Mater Sci Technol2022;117:133-45

[70]

Wang S,Zhang D,Manladan SM.Microstructure and mechanical properties of high strength AlCoCrFeNi2.1 eutectic high entropy alloy prepared by selective laser melting (SLM).Mater Lett2022;310:131511

[71]

Luo S,Wang Z.Tailored microstructures and strengthening mechanisms in an additively manufactured dual-phase high-entropy alloy via selective laser melting.Sci China Mater2020;63:1279-90

[72]

Luo S,Su Y,Wang Z.Selective laser melting of dual phase AlCrCuFeNix high entropy alloys: formability, heterogeneous microstructures and deformation mechanisms.Addit Manuf2020;31:100925

[73]

Nguyen T,Li H,Yang S.Microstructure and tensile properties of duplex phase Al0.25FeMnNiCrCu0.5 high entropy alloy fabricated by laser melting deposition.J Alloys Compd2021;871:159521

[74]

Guo Y,Zhou H et al.Unique strength-ductility balance of AlCoCrFeNi2.1 eutectic high entropy alloy with ultra-fine duplex microstructure prepared by selective laser melting.J Mater Sci Technol2022;111:298-306

[75]

Zhou R,Liu B,Fang Q.Precipitation behavior of selective laser melted FeCoCrNiC0.05 high entropy alloy.Intermetallics2019;106:20-5

[76]

Wu W,Wei B,Liu Y.Nanosized precipitates and dislocation networks reinforced C-containing CoCrFeNi high-entropy alloy fabricated by selective laser melting.Mater Charact2018;144:605-10

[77]

Kim Y-K,Kim HS.In-situ carbide-reinforced CoCrFeMnNi high-entropy alloy matrix nanocomposites manufactured by selective laser melting: carbon content effects on microstructure, mechanical properties, and deformation mechanism.Compos B Eng2021;210:108638

[78]

Zhu Z,Lu W et al.Selective laser melting enabling the hierarchically heterogeneous microstructure and excellent mechanical properties in an interstitial solute strengthened high entropy alloy.Mater Res Lett2019;7:453-9

[79]

Park JM,Kim JG et al.Superior tensile properties of 1% C-CoCrFeMnNi high-entropy alloy additively manufactured by selective laser melting.Mater Res Lett2020;8:1-7

[80]

Chen H,Wang Y et al.Laser additive manufacturing of nano-TiC particles reinforced CoCrFeMnNi high-entropy alloy matrix composites with high strength and ductility.Mater Sci Eng A2022;833:142512

[81]

Li B,Xu Y,Qian B.Selective laser melting of CoCrFeNiMn high entropy alloy powder modified with nano-TiN particles for additive manufacturing and strength enhancement: process, particle behavior and effects.Powder Technol2020;360:509-21

[82]

Li B,Xu Y,Xuan F.Fine-structured CoCrFeNiMn high-entropy alloy matrix composite with 12 wt% TiN particle reinforcements via selective laser melting assisted additive manufacturing. Mater. lett. 2019;252:88-91.

[83]

Chen P,Li S,Yan M.In-situ alloyed, oxide-dispersion-strengthened CoCrFeMnNi high entropy alloy fabricated via laser powder bed fusion.Mater Des2020;194:108966

[84]

Lin W-C,Hsu T-H et al.Microstructure and tensile property of a precipitation strengthened high entropy alloy processed by selective laser melting and post heat treatment.Addit Manuf2020;36:101601

[85]

Fujieda T,Shiratori H et al.Mechanical and corrosion properties of CoCrFeNiTi-based high-entropy alloy additive manufactured using selective laser melting.Addit Manuf2019;25:412-20

[86]

Fujieda T,Kuwabara K et al.CoCrFeNiTi-based high-entropy alloy with superior tensile strength and corrosion resistance achieved by a combination of additive manufacturing using selective electron beam melting and solution treatment.Mater Lett2017;189:148-51

[87]

Wu Y,Chen Q et al.Strengthening and fracture mechanisms of a precipitation hardening high-entropy alloy fabricated by selective laser melting.Virtual Phys Prototyp2022;17:451-67

[88]

Yao N,Feng K et al.Ultrastrong and ductile additively manufactured precipitation-hardening medium-entropy alloy at ambient and cryogenic temperatures.Acta Mater2022;236:118142

[89]

Mu Y,Deng S et al.A high-entropy alloy with dislocation-precipitate skeleton for ultrastrength and ductility.Acta Mater2022;232:117975

[90]

Chen J,Wang W et al.A review on fundamental of high entropy alloys with promising high-temperature properties.J Alloys Compd2018;760:15-30

[91]

Su Y,Wang Z.Microstructure evolution and cracking behaviors of additively manufactured AlxCrCuFeNi2 high entropy alloys via selective laser melting.J Alloys Compd2020;842:155823

[92]

Zhao D,Wang D et al.Ordered nitrogen complexes overcoming strength-ductility trade-off in an additively manufactured high-entropy alloy.Virtual Phys Prototyp2020;15:532-42

[93]

Ghayoor M,He Y,Paul BK.Selective laser melting of austenitic oxide dispersion strengthened steel: processing, microstructural evolution and strengthening mechanisms.Mater Sci Eng A2020;788:139532

[94]

Lee H,Kang D-S et al.Oxide dispersion strengthened IN718 owing to powder reuse in selective laser melting.Mater Sci Eng A2022;832:142369

[95]

Rittinghaus S-K.Oxide dispersion strengthening of γ-TiAl by laser additive manufacturing.J Alloys Compd2019;804:457-60

[96]

Kim Y-K,Yang S.In-situ formed oxide enables extraordinary high-cycle fatigue resistance in additively manufactured CoCrFeMnNi high-entropy alloy.Addit Manuf2021;38:101832

[97]

Kim Y-K,Lee K-A.Compressive creep behavior of selective laser melted CoCrFeMnNi high-entropy alloy strengthened by in-situ formation of nano-oxides.Addit Manuf2020;36:101543

[98]

Kim Y-K,Song Y,Yang S.Selective laser melted CrMnFeCoNi + 3 wt% Y2O3 high-entropy alloy matrix nanocomposite: fabrication, microstructure and nanoindentation properties.Intermetallics2021;138:107319

[99]

Kocks U.Physics and phenomenology of strain hardening: the FCC case.Prog Mater Sci2003;48:171-273

[100]

LaRosa CR,Varvenne C.Solid solution strengthening theories of high-entropy alloys.Mater Charact2019;151:310-7

[101]

Ishimoto T,Nakano K et al.Development of TiNbTaZrMo bio-high entropy alloy (BioHEA) super-solid solution by selective laser melting, and its improved mechanical property and biocompatibility.Scr Mater2021;194:113658

[102]

Zhang Y,Jayalakshmi S,Deev VB.Factors determining solid solution phase formation and stability in CoCrFeNiX0.4 (X = Al, Nb, Ta) high entropy alloys fabricated by powder plasma arc additive manufacturing.J Alloys Compd2021;857:157625

[103]

Agrawal P,Nene S,McWilliams B.Excellent strength-ductility synergy in metastable high entropy alloy by laser powder bed additive manufacturing.Addit Manuf2020;32:101098

[104]

Song X,Lu H,Tang F.Integrating computational materials science and materials informatics for the modeling of phase stability.J Mater Inf2021;1:7

[105]

Xi S,Bao L et al.Machine learning-accelerated first-principles predictions of the stability and mechanical properties of L12-strengthened cobalt-based superalloys.J Mater Inf2022;2:15

[106]

Yang Y,Han C-X et al.Taking materials dynamics to new extremes using machine learning interatomic potentials.J Mater Inf2021;1:10

[107]

Liu Y,Xiao B.Accelerated development of hard high-entropy alloys with data-driven high-throughput experiments.J Mater Inf2022;2:3

[108]

Yu J,Pan S et al.Machine learning-guided design and development of metallic structural materials.J Mater Inf2021;1:9

[109]

Huang W,Zhuang HL.Machine-learning phase prediction of high-entropy alloys.Acta Mater2019;169:225-36 PMCID:PMC9105637
[110]

Krishna YV,Rahul M.Machine learning approach to predict new multiphase high entropy alloys.Scr Mater2021;197:113804

[111]

Zhou Z,He Q,Li F.Machine learning guided appraisal and exploration of phase design for high entropy alloys.NPJ Comput Mater2019;5:1-9

[112]

Zhang Y,Wang C et al.Phase prediction in high entropy alloys with a rational selection of materials descriptors and machine learning models.Acta Mater2020;185:528-39

[113]

Lee SY,Kim HS,Lee S.Deep learning-based phase prediction of high-entropy alloys: optimization, generation, and explanation.Mater Des2021;197:109260

[114]

Wen C,Wang C et al.Machine learning assisted design of high entropy alloys with desired property.Acta Mater2019;170:109-17

[115]

Yang C,Jia Y,Li M.A machine learning-based alloy design system to facilitate the rational design of high entropy alloys with enhanced hardness.Acta Mater2022;222:117431

[116]

Bhandari U,Zhang C.Yield strength prediction of high-entropy alloys using machine learning.Mater Today Commun2021;26:101871

[117]

Zhang B,Bai Q.Defect formation mechanisms in selective laser melting: a review.Chin J Mech Eng2017;30:515-27

[118]

Zhou Y,Wang Y et al.Selective laser melting of typical metallic materials: an effective process prediction model developed by energy absorption and consumption analysis.Addit Manuf2019;25:204-17

[119]

Xiong W.Additive manufacturing as a tool for high-throughput experimentation.J Mater Inf2022;2:12

[120]

Westphal E.A machine learning method for defect detection and visualization in selective laser sintering based on convolutional neural networks.Addit Manuf2021;41:101965

[121]

Chen Y,Wu Y.Predicting the printability in selective laser melting with a supervised machine learning method.Materials2020;13:5063 PMCID:PMC7698234
[122]

Park HS,Le-Hong T.Machine learning-based optimization of process parameters in selective laser melting for biomedical applications.J Intell Manuf2022;33:1843-58

[123]

Zheng L,Meng Y,Schlesiger R.Mechanism of intermediate temperature embrittlement of Ni and Ni-based superalloys.Crit Rev Solid State Mater Sci2012;37:181-214

[124]

Yang T,Fan L et al.Control of nanoscale precipitation and elimination of intermediate-temperature embrittlement in multicomponent high-entropy alloys.Acta Mater2020;189:47-59

[125]

Cao B,Zhang X et al.Intermediate temperature embrittlement in a precipitation-hardened high-entropy alloy: the role of heterogeneous strain distribution and environmentally assisted intergranular damage.Mater Today Phys2022;24:100653

[126]

Tong Z,Jiao J,Yang Y.Laser additive manufacturing of CrMnFeCoNi high entropy alloy: microstructural evolution, high-temperature oxidation behavior and mechanism.Opt Laser Technol2020;130:106326

[127]

Zhong X,Liu S,Hiszpanski A.Explainable machine learning in materials science.NPJ Comput Mater2022;8:1-19

AI Summary AI Mindmap
PDF

170

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/