Effect of solution treatment on the microstructure, phase transformation behavior and functional properties of NiTiNb ternary shape memory alloys fabricated via laser powder bed fusion <i>in-situ</i> alloying

Rui Xi; Hao Jiang; Guichuan Li; Zhihui Zhang; Huiliang Wei; Guoqun Zhao; Jan Van Humbeeck; Xiebin Wang

doi:10.1088/2631-7990/ad35fc

Post-heat treatment is commonly employed to improve the microstructural homogeneity and enhance the mechanical performances of the additively manufactured metallic materials. In this work, a ternary (NiTi)₉₁Nb₉ (at.%) shape memory alloy was produced by laser powder bed fusion (L-PBF) using pre-alloyed NiTi and elemental Nb powders. The effect of solution treatment on the microstructure, phase transformation behavior and mechanical/functional performances was investigated. The in-situ alloyed (NiTi)₉₁Nb₉ alloy exhibits a submicron cellular-dendritic structure surrounding the supersaturated B2-NiTi matrix. Upon high-temperature (1273 K) solution treatment, Nb-rich precipitates were precipitated from the supersaturated matrix. The fragmentation and spheroidization of the NiTi/Nb eutectics occurred during solution treatment, leading to a morphological transition from mesh-like into rod-like and sphere-like. Coarsening of the β-Nb phases occurred with increasing holding time. The martensite transformation temperature increases after solution treatment, mainly attributed to: (i) reduced lattice distortion due to the Nb expulsion from the supersaturated B2-NiTi, and (ii) the Ti expulsion from the β-Nb phases that lowers the ratio Ni/Ti in the B2-NiTi matrix, which resulted from the microstructure changes from non-equilibrium to equilibrium state. The thermal hysteresis of the solutionized alloys is around 145 K after 20% pre-deformation, which is comparable to the conventional NiTiNb alloys. A short-term solution treatment (i.e. at 1 273 K for 30 min) enhances the ductility and strength of the as-printed specimen, with the increase of fracture stress from (613 ± 19) MPa to (781 ± 20) MPa and the increase of fracture strain from (7.6 ± 0.1)% to (9.5 ± 0.4)%. Both the as-printed and solutionized samples exhibit good tensile shape memory effects with recovery rates >90%. This work suggests that post-process heat treatment is essential to optimize the microstructure and improve the mechanical performances of the L-PBF in-situ alloyed parts.

HTML

Reference (88)

Otsuka K and Ren X 2005 Physical metallurgy of Ti–Ni-based shape memory alloys Prog. Mater. Sci. 50511–678

Kim W C, Lim K R, Kim W T, Park E S and Kim D H 2022 Recent advances in multicomponent NiTi-based shape memory alloy using metallic glass as a precursor Prog. Mater. Sci. 123100855

Simpson J A, Melton K and Duerig T 1986. Method of processing a nickel/titanium-based shape memory alloy and article produced therefrom U.S. Patent. No. 4631094

Ma J, Karaman I and Noebe R D 2010 High temperature shape memory alloys Int. Mater. Rev. 55257–315

Piao M, Miyazaki S, Otsuka K and Nishida N 1992 Effects of Nb addition on the microstructure of Ti–Ni alloys Mater. Trans. JIM 33337–45

Taylor S L, Ibeh A J, Jakus A E, Shah R N and Dunand D C 2018 NiTi-Nb micro-trusses fabricated via extrusion-based 3D-printing of powders and transient-liquid-phase sintering Acta Biomater. 76359–70

Wang L Q, Xie L C, Zhang L C, Chen L Y, Ding Z H, Lv Y T, Zhang W, Lu W J and Zhang D 2018 Microstructure evolution and superelasticity of layer-like NiTiNb porous metal prepared by eutectic reaction Acta Mater. 143214–26

Zhang Y T, Liu J, Wang L Q, Wei D X, Liu C X, Wang K S, Tang Y J, Zhang L and Lu W J 2022 Porous NiTiNb alloys with superior strength and ductility induced by modulating eutectic microregion Acta Mater. 239118295

Liu S F, Liu J B, Wang L Q, Ma R L W, Zhong Y S, Lu W J and Zhang L C 2020 Superelastic behavior of in-situ eutectic-reaction manufactured high strength 3D porous NiTi-Nb scaffold Scr. Mater. 181121–6

He X M, Rong L J, Yan D S and Li Y Y 2004 TiNiNb wide hysteresis shape memory alloy with low niobium content Mater. Sci. Eng. A 371193–7

Elahinia M H, Hashemi M, Tabesh M and Bhaduri S B 2012 Manufacturing and processing of NiTi implants: a review Prog. Mater. Sci. 57911–46

Fan Q C, Zhang Y, Zhang Y H, Wang Y Y, Yan E H, Huang S K and Wen Y H 2019 Influence of Ni/Ti ratio and Nb addition on martensite transformation behavior of NiTiNb alloys J. Alloys Compd. 7901167–76

Elahinia M, Shayesteh Moghaddam N, Taheri Andani M, Amerinatanzi A, Bimber B A and Hamilton R F 2016 Fabrication of NiTi through additive manufacturing: a review Prog. Mater. Sci. 83630–63

Oliveira J P, Miranda R M and Braz Fernandes F M 2017 Welding and joining of NiTi shape memory alloys: a review Prog. Mater. Sci. 88412–66

Hassan M R, Mehrpouya M and Dawood S 2014 Review of the machining difficulties of nickel-titanium based shape memory alloys Appl. Mech Mater. 564533–7

Tan C L et al 2021 Additive manufacturing of bio-inspired multi-scale hierarchically strengthened lattice structures Int. J. Mach. Tools Manuf. 167103764

Xiong Z W, Li H H, Yang H, Yang Y, Liu Y N, Cui L S, Li X X, Masseling L, Shen L Y W and Hao S J 2022 Micro laser powder bed fusion of NiTi alloys with superior mechanical property and shape recovery function Addit. Manuf. 57102960

Wei S S, Zhang J L, Zhang L, Zhang Y J, Song B, Wang X B, Fan J X, Liu Q and Shi Y S 2023 Laser powder bed fusion additive manufacturing of NiTi shape memory alloys: a review Int. J. Extrem. Manuf. 5032001

Chen W, Gu D D, Yang J K, Yang Q, Chen J and Shen X F 2022 Compressive mechanical properties and shape memory effect of NiTi gradient lattice structures fabricated by laser powder bed fusion Int. J. Extrem. Manuf. 4045002

Zhang T L, Huang Z H, Yang T, Kong H J, Luan J H, Wang A D, Wang D, Kuo W, Wang Y Z and Liu C T 2021 In situ design of advanced titanium alloy with concentration modulations by additive manufacturing Science 374478–82

Huang S, Kumar P, Yeong W Y, Narayan R L and Ramamurty U 2022 Fracture behavior of laser powder bed fusion fabricated Ti41Nb via in-situ alloying Acta Mater. 225117593

Montero-Sistiaga M L, Mertens R, Vrancken B, Wang X B, Van Hooreweder B, Kruth J P and Van Humbeeck J 2016 Changing the alloy composition of Al7075 for better processability by selective laser melting J. Mater. Process. Technol. 238437–45

Tan Q Y, Zhang J Q, Sun Q, Fan Z Q, Li G, Yin Y, Liu Y G and Zhang M X 2020 Inoculation treatment of an additively manufactured 2024 aluminium alloy with titanium nanoparticles Acta Mater. 1961–16

Zhu X J, Liu S, Wang X B and Wang G C 2023 Effect of solution and aging treatments on the microstructure and mechanical properties of dual-phase high-entropy alloy prepared by laser-powder bed fusion using AlSi10Mg and FeCoCrNi powders Addit. Manuf. 70103548

Wang C, Tan X P, Du Z, Chandra S, Sun Z, Lim C W J, Tor S B, Lim C S and Wong C H 2019 Additive manufacturing of NiTi shape memory alloys using pre-mixed powders J. Mater. Process. Technol. 271152–61

Zhang B C, Chen J and Coddet C 2013 Microstructure and transformation behavior of in-situ shape memory alloys by selective laser melting Ti–Ni mixed powder J. Mater. Sci. Technol. 29863–7

Hamilton R F, Bimber B A, Taheri Andani M and Elahinia M 2017 Multi-scale shape memory effect recovery in NiTi alloys additive manufactured by selective laser melting and laser directed energy deposition J. Mater. Process. Technol. 25055–64

Zhao C Y, Liang H L, Luo S C, Yang J J and Wang Z M 2020 The effect of energy input on reaction, phase transition and shape memory effect of NiTi alloy by selective laser melting J. Alloys Compd. 817153288

Chen J, Wang Z Y, Wang S, Xiang Z, Shen X F, Huang S K and Yang Q 2022 Mechanical and functional properties of HfH2-decorated NiTi shape memory alloy fabricated by laser powder-bed fusion J. Alloys Compd. 913165296

Xi R, Jiang H, Li G C, Zhang Z H, Zhao G Q, Vanmeensel K, Kustov S, Van Humbeeck J and Wang X B 2023 Effect of Fe addition on the microstructure, transformation behaviour and superelasticity of NiTi alloys fabricated by laser powder bed fusion Virtual Phys. Prototyp. 18 e2126376

Xi R, Jiang H, Kustov S, Zhang Z H, Zhao G Q, Vanmeensel K, Van Humbeeck J and Wang X B 2023 Influence of Nb addition and process parameters on the microstructure and phase transformation behavior of NiTiNb ternary shape memory alloys fabricated by laser powder bed fusion Scr. Mater. 222114996

Liu S F, Han S, Zhang L, Chen L Y, Wang L Q, Zhang L, Tang Y J, Liu J, Tang H P and Zhang L C 2020 Strengthening mechanism and micropillar analysis of high-strength NiTi–Nb eutectic-type alloy prepared by laser powder bed fusion Composites B 200108358

Polozov I and Popovich A 2021 Microstructure and mechanical properties of NiTi-based eutectic shape memory alloy produced via selective laser melting in-situ alloying by Nb Materials 142696

Vrancken B, Thijs L, Kruth J P and Van Humbeeck J 2014 Microstructure and mechanical properties of a novel β titanium metallic composite by selective laser melting Acta Mater. 68150–8

Wang J C, Liu Y J, Qin P, Liang S X, Sercombe T B and Zhang L C 2019 Selective laser melting of Ti–35Nb composite from elemental powder mixture: microstructure, mechanical behavior and corrosion behavior Mater. Sci. Eng. A 760214–24

Brodie E G, Medvedev A E, Frith J E, Dargusch M S, Fraser H L and Molotnikov A 2020 Remelt processing and microstructure of selective laser melted Ti25Ta J. Alloys Compd. 820153082

Saedi S, Turabi A S, Taheri Andani M, Haberland C, Karaca H and Elahinia M 2016 The influence of heat treatment on the thermomechanical response of Ni-rich NiTi alloys manufactured by selective laser melting J. Alloys Compd. 677204–10

Li S, Hassanin H, Attallah M M, Adkins N J E and Essa K 2016 The development of TiNi-based negative Poisson’s ratio structure using selective laser melting Acta Mater. 10575–83

Lu Z H et al 2022 Simultaneous enhancement of mechanical and shape memory properties by heat-treatment homogenization of Ti2Ni precipitates in TiNi shape memory alloy fabricated by selective laser melting J. Mater. Sci. Technol. 101205–16

Lu H Z, Ma H W, Cai W S, Luo X, Wang Z, Song C H, Yin S and Yang C 2021 Stable tensile recovery strain induced by a Ni4Ti3 nanoprecipitate in a Ni50.4Ti49.6 shape memory alloy fabricated via selective laser melting Acta Mater. 219117261

Cao Y X et al 2020 Large tunable elastocaloric effect in additively manufactured Ni–Ti shape memory alloys Acta Mater. 194178–89

Li X P, Wang X J, Saunders M, Suvorova A, Zhang L C, Liu Y J, Fang M H, Huang Z H and Sercombe T B 2015 A selective laser melting and solution heat treatment refined Al–12Si alloy with a controllable ultrafine eutectic microstructure and 25% tensile ductility Acta Mater. 9574–82

Deng J W, Chen C, Liu X C, Li Y P, Zhou K C and Guo S M 2021 A high-strength heat-resistant Al-5.7Ni eutectic alloy with spherical Al3Ni nano-particles by selective laser melting Scr. Mater. 203114034

Laleh M et al 2023 Heat treatment for metal additive manufacturing Prog. Mater. Sci. 133101051

Rasband W 2012 ImageJ (U.S. National Institutes of Health)

DebRoy T, Wei H L, Zuback J S, Mukherjee T, Elmer J W, Milewski J O, Beese A M, Wilson-Heid A, De A and Zhang W 2018 Additive manufacturing of metallic components—process, structure and properties Prog. Mater. Sci. 92112–224

Elmer J W, Allen S M and Eagar T W 1989 Microstructural development during solidification of stainless steel alloys Metall. Trans. A 202117–31

Wang X B, Kustov S and Van Humbeeck J 2018 A short review on the microstructure, transformation behavior and functional properties of NiTi shape memory alloys fabricated by selective laser melting Materials 111683

Muñoz J A, Elizalde S, Komissarov A and Cabrera J M 2022 Effect of heat treatments on the mechanical and microstructural behavior of a hypoeutectic Al alloy obtained by laser powder bed fusion Mater. Sci. Eng. A 857144091

Baldan A 2002 Review progress in Ostwald ripening theories and their applications to nickel-base superalloys Part I: Ostwald ripening theories J. Mater. Sci. 372171–202

Kai W Y, Chang K C, Wu H F, Chen S W and Yeh A C 2019 Formation mechanism of Ni2Ti4Ox in NITI shape memory alloy Materialia 5100194

Khairallah S A, Anderson A T, Rubenchik A and King W E 2016 Laser powder-bed fusion additive manufacturing: physics of complex melt flow and formation mechanisms of pores, spatter, and denudation zones Acta Mater. 10836–45

Yao L M, Huang S, Ramamurty U and Xiao Z M 2021 On the formation of “Fish-scale” morphology with curved grain interfacial microstructures during selective laser melting of dissimilar alloys Acta Mater. 220117331

Wang Y M et al 2018 Additively manufactured hierarchical stainless steels with high strength and ductility Nat. Mater. 1763–71

Marien J, Wagner T, Duscher G, Koch A and Rühle M 2000 Nb on (110) TiO2(rutile): growth, structure, and chemical composition of the interface Surf. Sci. 446219–28

Nico C, Monteiro T and Graça M P F 2016 Niobium oxides and niobates physical properties: review and prospects Prog. Mater. Sci. 801–37

Onda T, Piao M, Bando Y, Ichinose H and Otsuka K 1995 Electron microscopy study of the eutectic structure in Ti40Ni40Nb20 alloy Mater. Trans. JIM 3623–29

Shi H, Pourbabak S, Van Humbeeck J and Schryvers D 2012 Electron microscopy study of Nb-rich nanoprecipitates in Ni–Ti–Nb and their influence on the martensitic transformation Scr. Mater. 67939–42

Frenzel J, George E P, Dlouhy A, Somsen C, Wagner M F X and Eggeler G 2010 Influence of Ni on martensitic phase transformations in NiTi shape memory alloys Acta Mater. 583444–58

Xue L et al 2022 Laser powder bed fusion of defect-free NiTi shape memory alloy parts with superior tensile superelasticity Acta Mater. 229117781

Jiang H et al 2023 Size effect on the microstructure, phase transformation behavior, and mechanical properties of NiTi shape memory alloys fabricated by laser powder bed fusion J. Mater. Sci. Technol. 157200–12

Kürnsteiner P, Bajaj P, Gupta A, Wilms M B, Weisheit A, Li X S, Leinenbach C, Gault B, Jägle E A and Raabe D 2020 Control of thermally stable core-shell nano-precipitates in additively manufactured Al-Sc-Zr alloys Addit. Manuf. 32100910

Spierings A B, Dawson K, Dumitraschkewitz P, Pogatscher S and Wegener K 2018 Microstructure characterization of SLM-processed Al-Mg-Sc-Zr alloy in the heat treated and HIPed condition Addit. Manuf. 20173–81

Banumathy S, Prasad K S, Mandal R K and Singh A K 2011 Effect of thermomechanical processing on evolution of various phases in Ti–Nb alloys Bull. Mater. Sci. 341421–34

Joubert J M, Sundman B and Dupin N 2004 Assessment of the niobium–nickel system Calphad 28299–306

Huang K, Marthinsen K, Zhao Q L and Logé R E 2018 The double-edge effect of second-phase particles on the recrystallization behaviour and associated mechanical properties of metallic materials Prog. Mater. Sci. 92284–359

Maamoun A H, Elbestawi M, Dosbaeva G K and Veldhuis S C 2018 Thermal post-processing of AlSi10Mg parts produced by selective laser melting using recycled powder Addit. Manuf. 21234–47

Ehtemam-Haghighi S, Liu Y J, Cao G H and Zhang L C 2016 Phase transition, microstructural evolution and mechanical properties of Ti-Nb-Fe alloys induced by Fe addition Mater. Des. 97279–86

He X M and Rong L J 2004 DSC analysis of reverse martensitic transformation in deformed Ti–Ni–Nb shape memory alloy Scr. Mater. 517–11

Zhao X Q, Yan X M, Yang Y Z and Xu H B 2006 Wide hysteresis NiTi(Nb) shape memory alloys with low Nb content (4.5at.%) Mater. Sci. Eng. A 438–440575–8

Wang X B et al 2020 Effect of process parameters on the phase transformation behavior and tensile properties of NiTi shape memory alloys fabricated by selective laser melting Addit. Manuf. 36101545

Frenzel J, Zhang Z, Somsen C, Neuking K and Eggeler G 2007 Influence of carbon on martensitic phase transformations in NiTi shape memory alloys Acta Mater. 551331–41

Wang M J, Jiang M Y, Liao G Y, Guo S and Zhao X Q 2012 Martensitic transformation involved mechanical behaviors and wide hysteresis of NiTiNb shape memory alloys Prog. Nat. Sci. 22130–8

Sun M Y, Chen J, Fan Q C, Yang C, Wang G W, Shen X F, Wang Y Y, Zhang Y H and Huang S K 2022 Transformation behavior and shape memory effect of Ni47Ti44Nb9 alloy synthesized by laser powder bed fusion and heat treating Metals 121438

Zhang C S, Zhao L C, Duerig T W and Wayman C M 1990 Effects of deformation on the transformation hysteresis and shape memory effect in a Ni47Ti44Nb9 alloy Scr. Metall. Mater. 241807–12

Guo W Q, Feng B, Yang Y, Ren Y, Liu Y N, Yang H, Yang Q, Cui L S, Tong X and Hao S J 2022 Effect of laser scanning speed on the microstructure, phase transformation and mechanical property of NiTi alloys fabricated by LPBF Mater. Des. 215110460

Kang N, Coddet P, Ammar M R, Liao H L and Coddet C 2017 Characterization of the microstructure of a selective laser melting processed Al-50Si alloy: effect of heat treatments Mater. Charact. 130243–9

Li W, Li S, Liu J, Zhang A, Zhou Y, Wei Q S, Yan C Z and Shi Y S 2016 Effect of heat treatment on AlSi10Mg alloy fabricated by selective laser melting: microstructure evolution, mechanical properties and fracture mechanism Mater. Sci. Eng. A 663116–25

Mukherjee T, Elmer J W, Wei H L, Lienert T J, Zhang W, Kou S and Debroy T 2023 Control of grain structure, phases, and defects in additive manufacturing of high-performance metallic components Prog. Mater. Sci. 138101153

Prasad A, Yuan L, Lee P, Patel M, Qiu D, Easton M and Stjohn D 2020 Towards understanding grain nucleation under additive manufacturing solidification conditions Acta Mater. 195392–403

Tan Q Y, Yin Y, Prasad A, Li G, Zhu Q, Stjohn D H and Zhang M X 2022 Demonstrating the roles of solute and nucleant in grain refinement of additively manufactured aluminium alloys Addit. Manuf. 49102516

Li G C, Brodu E, Soete J, Wei H L, Liu T T, Yang T, Liao W H and Vanmeensel K 2021 Exploiting the rapid solidification potential of laser powder bed fusion in high strength and crack-free Al-Cu-Mg-Mn-Zr alloys Addit. Manuf. 47102210

Liu Y J, Liu Z, Jiang Y, Wang G W, Yang Y and Zhang L C 2018 Gradient in microstructure and mechanical property of selective laser melted AlSi10Mg J. Alloys Compd. 7351414–21

Chen Y, Xiao C W, Zhu S, Li Z W, Yang W X, Zhao F, Yu S F and Shi Y S 2022 Microstructure characterization and mechanical properties of crack-free Al-Cu-Mg-Y alloy fabricated by laser powder bed fusion Addit. Manuf. 58103006

Ogris E, Wahlen A, Lüchinger H and Uggowitzer P J 2002 On the silicon spheroidization in Al–Si alloys J. Light Met. 2263–9

Páramo V, Colás R, Velasco E and Valtierra S 2000 Spheroidization of the Al-Si eutectic in a cast aluminum alloy J. Mater. Eng. Perform. 9616–22

Ibrahim M, Abdelaziz M, Samuel A, Doty H and Samuel F 2021 Spheroidization and coarsening of eutectic Si particles in Al-Si-based alloys Adv. Mater. Sci. Eng. 20211–16

Saedi S, Moghaddam N S, Amerinatanzi A, Elahinia M and Karaca H E 2018 On the effects of selective laser melting process parameters on microstructure and thermomechanical response of Ni-rich NiTi Acta Mater. 144552–60

Effect of solution treatment on the microstructure, phase transformation behavior and functional properties of NiTiNb ternary shape memory alloys fabricated via laser powder bed fusion in-situ alloying

doi: 10.1088/2631-7990/ad35fc

Abstract

Keywords

通讯作者: 陈斌, bchen63@163.com

Article Metrics

Effect of solution treatment on the microstructure, phase transformation behavior and functional properties of NiTiNb ternary shape memory alloys fabricated via laser powder bed fusion in-situ alloying

doi: 10.1088/2631-7990/ad35fc

HTML

Catalog

Publish with IJEM

Contact us

Quick Links

Effect of solution treatment on the microstructure, phase transformation behavior and functional properties of NiTiNb ternary shape memory alloys fabricated via laser powder bed fusion in-situ alloying

doi: 10.1088/2631-7990/ad35fc

Abstract

Keywords

通讯作者: 陈斌, bchen63@163.com

Article Metrics

Effect of solution treatment on the microstructure, phase transformation behavior and functional properties of NiTiNb ternary shape memory alloys fabricated via laser powder bed fusion in-situ alloying

doi: 10.1088/2631-7990/ad35fc

HTML

Catalog

Publish with IJEM

Contact us

Quick Links

Export File

Citation

Format

Content