References
- Banerjee D, Williams JC. Perspectives on titanium science and technology. Acta Mater. 2013;61:844–879.
- Antunes RA, Salvador CAF, Oliveira MCLD. Materials selection of optimized titanium alloys for aircraft applications. Mater Res. 2018;21:56–60.
- Froes FH, Mashl SJ, Moxson VS, et al. The technologies of titanium powder metallurgy. JOM. 2004;56:46–48.
- EI-Soudani SM, Yu K, Crist EM, et al. Optimization of blended-elemental powder-based titanium alloy extrusions for aerospace applications. Metall Mater Trans A. 2013;44:899–910.
- Lu BX, Yang F, Shao YR, et al. In-situ tensile deformation behavior of powder metallurgy Ti6Al4V alloys. Int J Refract Met H. 2020;91:105266.
- Bolzoni L, Ruiz-Navas EM, Gordo E. Quantifying the properties of low-cost powder metallurgy titanium alloys. Mater Sci Eng A. 2017;687:47–53.
- Shen J, Chen B, Umeda J, et al. Microstructure and mechanical properties of CP-Ti fabricated via powder metallurgy with non-uniformly dispersed impurity solutes. Mater Sci Eng A. 2018;716:1–10.
- Bolzoni L, Raynova S, Yang F. Work hardening of microwave sintered blended elemental Ti alloys. J Alloys Compd. 2020;838:155559.
- Dunstan MK, Paramore JD, Fang ZZ. The effects of microstructure and porosity on the competing fatigue failure mechanisms in powder metallurgy Ti-6Al-4V. Int J Fatigue. 2018;116:584–591.
- Ding RG, Chu MQ, Zhang SY. A study of microstructure and mechanical property of a burn-resistant Ti alloy fabricated by HIPping. Mater Charact. 2020;163:110280.
- Lu Y, Aristizabal M, Wang X, et al. The influence of heat treatment on the microstructure and properties of HIPped Ti-6Al-4V. Acta Mater. 2019;165:520–527.
- Narra SP, Wu ZH, Patal R, et al. Use of non-spherical hydride-dehydride powder in powder bed fusion additive manufacturing. Addit Manuf. 2020;34:101188.
- Abena A, Aristizabal M, Essa K. Comprehensive numerical modelling of the hot isostatic pressing of Ti-6Al-4V powder: from filling to consolidation. Adv Powder Technol. 2019;30:2451–2463.
- Liu J, Qin Y, Zheng J, et al. New approach to achieve high strength powder metallurgy Ti-6Al-4V alloy through a simplified hydrogenation-dehydrogenation treatment. J Alloys Compd. 2018;763:111–119.
- Oh J, Roh K, Lee B, et al. Preparation of low oxygen content alloy powder from Ti binary alloy scrap by hydrogenation-dehydrogenation and deoxidation process. J Alloys Compd. 2014;593:61–66.
- Zhang C, Lu BX, Wang HY, et al. Vacuum pressureless sintering of Ti-6Al-4V alloy with full densification and forged-like mechanical properties. J Mater Eng Perform. 2018;27:282–292.
- Zhang C, Yang F, Guo ZM, et al. Oxygen scavenging, grain refinement and mechanical properties improvement in powder metallurgy titanium and titanium alloys with CaB6. Powder Technol. 2018;340:362–369.
- Quan GZ, Zhang L, Wang X, et al. Correspondence between microstructural evolution mechanisms and hot processing parameters for Ti-13Nb-13Zr biomedical alloy in comprehensive processing maps. J Alloys Compd. 2017;698:178–193.
- Qiu JW, Liu Y, Liu B, et al. Microstructures and mechanical properties of titanium alloy connecting rod made by powder forging process. Mater Des. 2012;33:213–219.
- Yang JL, Wang GF, Jiao XY, et al. High-temperature deformation behavior of the extruded Ti-22Al-25Nb alloy fabricated by powder metallurgy. Mater Charact. 2018;137:170–179.
- Jha JS, Toppo SP, Singh R, et al. Flow stress constitutive relationship between lamellar and equiaxed microstructure during hot deformation of Ti-6Al-4V. J Mater Process Technol. 2019;270:216–227.
- Park NK, Yeom JT, Na YS. Characterization of deformation stability in hot forging of conventional Ti-6Al-4V using processing maps. J Mater Process Technol. 2002;130-131:540–545.
- Zhang ZX, Qu SJ, Feng AH, et al. Hot deformation behavior of Ti-6Al-4V alloy: effect of initial microstructure. J Alloys Compd. 2017;718:170–181.
- Long S, Xia YF, Hu JC, et al. Hot deformation behavior and microstructure evolution of Ti-6Cr-5Mo-5V-4Al alloy during hot compression. Vacuum. 2019;160:171–180.
- Wang M, Zhou JX, Yin YJ, et al. Hot deformation behavior of the Ti6Al4V alloy prepared by powder hot isostatic pressing. J Alloys Compd. 2017;721:320–332.
- Liu Z, Zhao ZB, Liu JR, et al. Deformation behaviors of as-built and hot isostatically pressed Ti-6Al-4V alloys fabricated via electron beam rapid manufacturing. J Mater Sci Technol. 2019;35:2552–2558.
- Yang YF, Luo SD, Qian M. The effect of lanthanum boride on the sintering, sintered microstructure and mechanical properties of titanium and titanium alloys. Mater Sci Eng A. 2014;618:447–455.
- Sellars CM, McTegart WJ. On the mechanism of hot deformation. Acta Metall. 1966;14:1136–1138.
- Peng X, Guo H, Shi Z, et al. Study on the hot deformation behavior of TC4-DT alloy with equiaxed α+β starting structure based on processing map. Mater Sci Eng A. 2014;605:80–88.
- Prasad YVRK, Sastry DH, Deevi SC. Processing maps for hot working of a P/M iron aluminide alloy. Intermetallics. 2000;8:1067–1074.
- Sun Y, Wan ZP, Hu LX, et al. Characterization of hot processing parameters of powder metallurgy TiAl-based alloy based on the activation energy map and processing map. Mater Design. 2015;86:922–932.
- Seshacharyulu T, Medeiros SC, Frazier WG, et al. Microstructural mechanisms during hot working of commercial grade Ti-6Al-4V with lamellar starting structure. Mater Sci Eng A. 2002;325:112–125.
- Huang K, Loge RE. A review of dynamic recrystallization phenomena in metallic materials. Mater Design. 2016;111:548–574.
- Semiatin SL, Seetharaman V, Weiss I. Flow behavior and globularization kinetics during hot working of Ti-6Al-4V with a colony alpha microstructure. Mater Sci Eng A. 1999;263:257–271.
- Seshacharyulu T, Medeiros SC, Frazier WG, et al. Hot working of commercial Ti-6Al-4V with an equiaxed α-β microstructure: materials modeling considerations. Mater Sci Eng A. 2000;284:184–194.