Advanced search
Publication Cover
Virtual and Physical Prototyping Volume 16, 2021 - Issue sup1: Additive Manufacturing of Advanced Materials and Structures for Sustainable Applications. Guested edited by Prof Kun Zhou, Prof Changjun Han and Prof Lianyong Xu.
Submit an article Journal homepage
4,752
Views
17
CrossRef citations to date
0
Altmetric
Articles

Additively manufacturing-enabled hierarchical NiTi-based shape memory alloys with high strength and toughness

Dongdong Gua College of Materials Science and Technology, Nanjing University of Aeronautics and Astronautics, Nanjing, People’s Republic of ChinaCorrespondence[email protected]
View further author information
,
Chenglong Mab School of Mechanical Engineering, Jiangnan University, Wuxi, People’s Republic of ChinaView further author information
,
Donghua Daia College of Materials Science and Technology, Nanjing University of Aeronautics and Astronautics, Nanjing, People’s Republic of ChinaView further author information
,
Jiankai Yanga College of Materials Science and Technology, Nanjing University of Aeronautics and Astronautics, Nanjing, People’s Republic of ChinaView further author information
,
Kaijie Lina College of Materials Science and Technology, Nanjing University of Aeronautics and Astronautics, Nanjing, People’s Republic of ChinaView further author information
,
Hongmei Zhanga College of Materials Science and Technology, Nanjing University of Aeronautics and Astronautics, Nanjing, People’s Republic of ChinaView further author information
&
Han Zhanga College of Materials Science and Technology, Nanjing University of Aeronautics and Astronautics, Nanjing, People’s Republic of ChinaView further author information
 show all
Pages S19-S38 | Received 13 Dec 2020, Accepted 16 Feb 2021, Published online: 10 Mar 2021

References

  • Andani, M. T., S. Saedi, A. S. Turabi, M. R. Karamooz, C. Haberland, H. E. Karaca, and M. Elahinia. 2017. “Mechanical and Shape Memory Properties of Porous Ni50.1Ti49.9 Alloys Manufactured by Selective Laser Melting.” Journal of the Mechanical Behavior of Biomedical Materials 68: 224–231.
  • Andrews, E., W. Sanders, and L. J. Gibson. 1999. “Compressive and Tensile Behaviour of Aluminum Foams.” Materials Science and Engineering A 270: 113–124.
  • Bouville, F., E. Maire, S. Meille, B. Van de Moortèle, A. J. Stevenson, and S. Deville. 2014. “Strong, Tough and Stiff Bioinspired Ceramics from Brittle Constituents.” Nature Materials 13: 508–514.
  • Bunge, H. J. 1993. Texture Analysis in Materials Science. Mathematical Methods. Göttingen: Cuvillier Verlag.
  • Bührig-Polaczek, A., C. Fleck, T. Speck, P. Schüler, S. F. Fischer, M. Caliaro, and M. Thielen. 2016. “Biomimetic Cellular Metals – Using Hierarchical Structuring for Energy Absorption.” Bioinspiration & Biomimetics 11: 045002.
  • Chuprina, V. G., and I. M. Shalya. 2002. “Reactions of TiNi with Oxygen.” Powder Metallurgy and Metal Ceramics 41: 85–89.
  • Cunningham, R., C. Zhao, N. Parab, C. Kantzos, J. Pauza, K. Fezzaa, T. Sun, and A. D. Rollett. 2019. “Keyhole Threshold and Morphology in Laser Melting Revealed by Ultrahigh-Speed X-Ray Imaging.” Science 363: 849–852.
  • Dadbakhsh, S., M. Speirs, J.-P. Kruth, and J. V. Humbeeck. 2015. “Influence of LPBF on Shape Memory and Compression Behaviour of NiTi Scaffolds.” CIRP Annals – Manufacturing Technology 64: 209–212.
  • Dadbakhsh, S., B. Vrancken, J.-P. Kruth, J. Luyten, and J. V. Humbeeck. 2016. “Texture and Anisotropy in Selective Laser Melting of NiTi Alloy.” Materials Science & Engineering A 650: 225–232.
  • Du, L., D. D. Gu, D. H. Dai, Q. M. Shi, C. L. Ma, and M. J. Xia. 2018. “Relation of Thermal Behavior and Microstructure Evolution During Multi-Track Laser Melting Deposition of Ni-Based Material.” Optics & Laser Technology 108: 207–217.
  • Elahinia, M. H., M. Hashemi, M. Tabesh, and S. B. Bhaduri. 2012. “Manufacturing and Processing of NiTi Implants: a Review.” Progress in Material Science 57: 911–946.
  • Elahinia, M., N. S. Moghaddam, M. T. Andani, A. Amerinatanzi, B. A. Bimber, and R. F. Hamilton. 2016. “Fabrication of NiTi Through Additive Manufacturing: A Review.” Progress in Materials Science 83: 630–663.
  • Fan, Q. C., Y. H. Zhang, Y. Y. Wang, M. Y. Sun, Y. T. Meng, S. K. Huang, and Y. H. Wen. 2017. “Influences of Transformation Behavior and Precipitates on the Deformation Behavior of Ni-Rich NiTi Alloys.” Materials Science and Engineering: A 700: 269–280.
  • Farvizi, M., M. R. Akbarpour, D.-H. Ahn, and H. S. Kim. 2016. “Compressive Behavior of NiTi-Based Composites Reinforced with Alumina Nanoparticles.” Journal of Alloys and Compounds 688: 803–807.
  • Finlay, W. L., and J. A. Snyder. 1950. “Effects of Three Interstitial Solutes (Nitrogen, Oxygen, and Carbon) on the Mechanical Properties of High-Purity, Alpha Titanium.” Transactions AIME- Journal of Metals 188: 277–286.
  • Franco, B. E., J. Ma, B. Loveall, G. A. Tapia, K. Karayagiz, J. Liu, A. Elwany, R. Arroyave, and I. Karaman. 2017. “A Sensory Material Approach for Reducing Variability in Additively Manufactured Metal Parts.” Scientific Reports 7: 3604.
  • Frenzel, J., E. P. George, A. Dlouhy, C. Somsen, M. F.-X. Wagner, and G. Eggeler. 2010. “Influence of Ni on Martensitic Phase Transformations in NiTi Shape Memory Alloys.” Acta Materialia 58: 3444–3458.
  • Gu, D., H. Chen, D. Dai, C. Ma, H. Zhang, K. Lin, L. Xi, et al. 2020. “Carbon Nanotubes Enabled Laser 3D Printing of High-Performance Titanium with Highly Concentrated Reinforcement.” IScience 23: 101498.
  • Gu, D. D., and B. B. He. 2016. “Finite Element Simulation and Experimental Investigation of Residual Stresses in Selective Laser Melted Ti-Ni Shape Memory Alloy.” Computational Materials Science 117: 221–232.
  • Han, C., Q. Fang, Y. Shi, S. B. Tor, C. K. Chua, and K. Zhou. 2020. “Recent Advances on High-Entropy Alloys for 3D Printing.” Advanced Materials 32: 1903855.
  • He, M. Y., and J. W. Hutchinson. 1989. “Crack Deflection at an Interface Between Dissimilar Elastic Materials.” International Journal of Solids and Structures 25: 1053–1067.
  • Hou, H., E. Simsek, T. Ma, N. S. Johnson, S. Qian, C. Cissé, D. Stasak, et al. 2019. “Fatigue-Resistant High-Performance Elastocaloric Materials Via Additive Manufacturing.” Science 366: 1116–1121.
  • Lei, Z., X. Liu, Y. Wu, H. Wang, S. Jiang, S. Wang, X. Hui, et al. 2018. “Enhanced Strength and Ductility in a High-Entropy Alloy Via Ordered Oxygen Complexes.” Nature 563: 546–550.
  • Lenau, T., and M. Barfoed. 2008. “Colours and Metallic Sheen in Beetle Shells – A Biomimetic Search for Material Structuring Principles Causing Light Interference.” Advanced Engineering Materials 10: 299–314.
  • Leung, C. L. A., S. Marussi, R. C. Atwood, M. Towrie, P. J. Withers, and P. D. Lee. 2018. “In Situ X-Ray Imaging of Defect and Molten Pool Dynamics in Laser Additive Manufacturing.” Nature Communications 9: 1355.
  • Li, S., H. Hassanin, M. M. Attallah, N. J. E. Adkins, and K. Essa. 2016. “The Development of TiNi-Based Negative Poisson’s Ratio Structure Using Selective Laser Melting.” Acta Materialia 105: 75–83.
  • Li, X., Z. Yang, and Z. Lu. 2019. “Design 3D Metamaterials with Compression-Induced-Twisting Characteristics Using Shear–Compression Coupling Effects.” Extreme Mechanics Letters 29: 100471.
  • Li, J., X. Zhou, M. Brochu, N. Provatas, and Y. F. Zhao. 2020. “Solidification Microstructure Simulation of Ti-6Al-4V in Metal Additive Manufacturing: A Review.” Additive Manufacturing 31: 100989.
  • Lin, X., T. M. Yue, H. O. Yang, and W. D. Huang. 2006. “Microstructure and Phase Evolution in Laser Rapid Forming of a Functionally Graded Ti–Rene88DT Alloy.” Acta Materialia 54: 1901.
  • Lu, B., X. Cui, W. Ma, M. Dong, Y. Fang, X. Wen, G. Jin, and D. Zeng. 2020. “Promoting the Heterogeneous Nucleation and the Functional Properties of Directed Energy Deposited NiTi Alloy by Addition of La2O3.” Additive Manufacturing 33: 101150.
  • Ma, J., B. Franco, G. Tapia, K. Karayagiz, L. Johnson, J. Liu, R. Arroyave, I. Karaman, and A. Elwany. 2017. “Spatial Control of Functional Response in 4D-Printed Active Metallic Structures.” Scientific Reports 7: 46707.
  • Ma, C., D. Gu, D. Dai, M. Xia, and H. Chen. 2018a. “Selective Growth of Ni4Ti3 Precipitate Variants Induced by Complicated Cyclic Stress During Laser Additive Manufacturing of NiTi-Based Composites.” Materials Characterization 143: 191–196.
  • Ma, C. L., D. D. Gu, D. H. Dai, H. M. Zhang, L. Du, and H. Zhang. 2018b. “Development of Interfacial Stress During Selective Laser Melting of TiC Reinforced TiAl Composites: Influence of Geometric Feature of Reinforcement.” Materials & Design 157: 1–11.
  • Ma, C., D. Gu, K. Lin, D. Dai, M. Xia, J. Yang, and H. Wang. 2019. “Selective Laser Melting Additive Manufacturing of Cancer Pagurus’s Claw Inspired Bionic Structures with High Strength and Toughness.” Applied Surface Science 469: 647–656.
  • Mahmoudi, M., G. Tapia, B. Franco, J. Ma, R. Arroyave, I. Karaman, and A. Elwany. 2018. “On the Printability and Transformation Behavior of Nickel-Titanium Shape Memory Alloys Fabricated Using Laser Powder-bed Fusion Additive Manufacturing.” Journal of Manufacturing Processes 35: 672–680.
  • Mehrabi, R., M. T. Andani, M. Kadkhodaei, and M. Elahinia. 2015. “Experimental Study of NiTi Thin-Walled Tubes Under Uniaxial Tension, Torsion, Proportional and Non-Proportional Loadings.” Experimental Mechanics 55: 1151–1164.
  • Meisner, L. L., A. B. Markov, D. I. Proskurovsky, V. P. Rotshtein, G. E. Ozur, S. N. Meisne, E. V. Yakovlev, T. M. Poletika, S. L. Girsova, and V. O. Semin. 2016. “Effect of Inclusions on Cratering Behavior in TiNi Shape Memory Alloys Irradiated with a Low-Energy, High-Current Electron Beam.” Surface and Coatings Technology 302: 495–506.
  • Mitchell, A., U. Lafont, M. Hołyńska, and C. Semprimoschnig. 2018. “Additive Manufacturing – A Review of 4D Printing and Future Applications.” Additive Manufacturing 24: 606–626.
  • Nagarajan, R., and K. Chattopadhyay. 1994. “Intermetallic Ti2Ni/TiNi Nanocomposite by Rapid Solidification.” Acta Metallurgica et Materialia 42: 947–958.
  • Naleway, S. E., M. M. Porter, J. McKittrick, and M. A. Meyers. 2015. “Structural Design Elements in Biological Materials: Application to Bioinspiration.” Advanced Materials 27: 5455–5476.
  • Nembach, E. 1983. “Precipitation Hardening Caused by a Difference in Shearing Modulus Between Particle and Matrix.” Physica Status Solidi 78: 571–581.
  • Olurin, O. B., N. A. Fleck, and M. F. Ashby. 2000. “Deformation and Fracture of Aluminium Foams.” Materials Science and Engineering A 291: 136–146.
  • Otsuka, K., and X. Ren. 2005. “Physical Metallurgy of Ti-Ni-Based Shape Memory Alloys.” Progress in Materials Science 50: 511–678.
  • Parab, N. D., C. Zhao, R. Cunningham, L. I. Escano, K. Fezzaa, W. Everhart, A. D. Rollett, L. Chen, and T. Sun. 2018. “Ultrafast X-Ray Imaging of Laser–Metal Additive Manufacturing Processes.” Journal of Synchrotron Radiation 25: 1467–1477.
  • Saedi, S., N. S. Moghaddam, A. Amerinatanzi, M. Elahinia, and H. E. Karaca. 2018. “On the Effects of Selective Laser Melting Process Parameters on Microstructure and Thermomechanical Response of Ni-Rich NiTi.” Acta Materialia 144: 552–560.
  • Saedi, S., A. S. Turabi, M. T. Andani, N. S. Moghaddam, M. Elahinia, and H. E. Karaca. 2017. “Texture, Aging, and Superelasticity of Selective Laser Melting Fabricated Ni-Rich NiTi Alloys.” Materials Science & Engineering A 686: 1–10.
  • Sam, J., B. Franco, J. Ma, I. Karaman, A. Elwany, and J. H. Mabe. 2018. “Tensile Actuation Response of Additively Manufactured Nickel-Titanium Shape Memory Alloys.” Scripta Materialia 146: 164–168.
  • Suksangpanya, N., N. A. Yaraghi, R. B. Pipes, D. Kisailus, and P. Zavattieri. 2018. “Crack Twisting and Toughening Strategies in Bouligand Architectures.” International Journal of Solids and Structures 150: 83–106.
  • Šittner, P., L. Heller, J. Pilch, C. Curfs, T. Alonso, and D. Favier. 2014. “Young’s Modulus of Austenite and Martensite Phases in Superelastic NiTi Wires.” Journal of Materials Engineering and Performance 23: 2303–2314.
  • Takeshita, H. T., H. Tanaka, N. Kuriyama, T. Sakai, I. Uehara, and M. Haruta. 2000. “Hydrogenation Characteristics of Ternary Alloys Containing Ti4Ni2X (X = O, N, C).” Journal of Alloys and Compounds 311: 188–193.
  • Taylor, S. L., A. J. Ibeh, A. E. Jakus, R. N. Shah, and D. C. Dunand. 2018. “NiTi-Nb Micro-Trusses Fabricated via Extrusion-Based 3D-Printing of Powders and Transient-Liquid-Phase Sintering.” Acta Biomaterialia 76: 359–370.
  • Toprek, D., J. Belosevic-Cavor, and V. Koteski. 2015. “Ab Initio Studies of the Structural, Elastic, Electronic and Thermal Properties of NiTi2 Intermetallic.” Journal of Physics and Chemistry of Solids 85: 197–205.
  • Toro, A., F. Zhou, M. H. Wu, W. V. Geertruyden, and W. Z. Misiolek. 2009. “Characterization of Non-Metallic Inclusions in Superelastic NiTi Tubes.” Journal of Materials Engineering and Performance 18: 448–458.
  • Vyatskikh, A., S. Delalande, A. Kudo, X. Zhang, C. M. Portela, and J. R. Greer. 2018. “Additive Manufacturing of 3D Nano-Architected Metals.” Nature Communications 9: 593.
  • Wang, X., M. Speirs, S. Kustov, B. Vrancken, X. Li, J.-P. Kruth, and J. V. Humbeeck. 2018a. “Selective Laser Melting Produced Layer-Structured NiTi Shape Memory Alloys with High Damping Properties and Elinvar Effect.” Scripta Materialia 146: 246–250.
  • Wang, Y. M., T. Voisin, J. T. McKeown, J. Ye, N. P. Calta, Z. Li, Z. Zeng, et al. 2018b. “Additively Manufactured Hierarchical Stainless Steels with High Strength and Ductility.” Nature Materials 17: 63.
  • Wang, X., J. Yu, J. Liu, L. Chen, Q. Yang, H. Wei, J. Sun, 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.” Additive Manufacturing 36: 101545.
  • Weaver, J. C., G. W. Milliron, A. Miserez, K. Evans-Lutterodt, S. Herrera, I. Gallana, W. J. Mershon, et al. 2012. “The Stomatopod Dactyl Club: A Formidable Damage-Tolerant Biological Hammer.” Science 336: 1275–1281.
  • Zhang, J. X., M. Sato, and A. Ishida. 2003. “On the Ti2Ni Precipitates and Guinier–Preston Zones in Ti-Rich Ti–Ni Thin Films.” Acta Materialia 51: 3121–3130.
  • Zhao, C., K. Fezzaa, R. W. Cunningham, H. Wen, F. D. Carlo, L. Chen, A. D. Rollett, and T. Sun. 2017. “Real-Time Monitoring of Laser Powder Bed Fusion Process Using High-Speed X-Ray Imaging and Diffraction.” Scientific Reports 7: 3602.
  • Zhao, C., Q. Guo, X. Li, N. Parab, K. Fezzaa, W. Tan, L. Chen, and T. Sun. 2019. “Bulk-Explosion-Induced Metal Spattering During Laser Processing.” Physical Review X 9: 021052.
  • Zhao, C., N. D. Parab, X. Li, K. Fezzaa, W. Tan, A. D. Rollett, and T. Sun. 2020. “Critical Instability at Moving Keyhole Tip Generates Porosity in Laser Melting.” Science 370: 1080–1086.
  • Zheng, X., W. Smith, J. Jackson, B. Moran, H. Cui, D. Chen, J. Ye, et al. 2016. “Multiscale Metallic Metamaterials.” Nature Materials 15: 1100.
  • Zhou, Q., M. D. Hayat, G. Chen, S. Cai, X. Qu, H. Tang, and P. Cao. 2019. “Selective Electron Beam Melting of NiTi: Microstructure, Phase Transformation and Mechanical Properties.” Materials Science & Engineering A 744: 290–298.
  • Zhu, Z. G., X. H. An, W. J. Lu, Z. M. Li, F. L. Ng, X. Z. Liao, U. Ramamurty, S. M. L. Nai, and J. Wei. 2019. “Selective Laser Melting Enabling the Hierarchically Heterogeneous Microstructure and Excellent Mechanical Properties in an Interstitial Solute Strengthened High Entropy Alloy.” Materials Research Letters 7: 453–459.
  • Zhu, C., Z. Qi, V. A. Beck, M. Luneau, J. Lattimer, W. Chen, M. A. Worsley, J. C. Ye, E. B. Duoss, and C. M. Spadaccini. 2018. “Toward Digitally Controlled Catalyst Architectures: Hierarchical Nanoporous Gold via 3D Printing.” Science Advance 4: 9459–9490.
  • Zimmermann, E. A., B. Gludovatz, E. Schaible, N. K. N. Dave, W. Yang, M. A. Meyers, and R. O. Ritchie. 2013. “Mechanical Adaptability of the Bouligand-Type Structure in Natural Dermal Armour.” Nature Communications 4: 2634.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.