Segregation mediated heterogeneous structure in a metastable β titanium alloy with a superior combination of strength and ductility

Gao, Junheng; Nutter, John; Liu, Xingguang; Guan, Dawei; Huang, Yuhe; Dye, David; Rainforth, W.M.

doi:10.1038/s41598-018-25899-3

Cited by 26 publications

(14 citation statements)

References 61 publications

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“…The experimental temperature was 1873 K and was controlled within ±2 K using a B-type (Pt-30%Rh/ Pt-6%Rh) thermocouple and a proportional integral differential controller. After the temperature stabilized, a mixture of ilmenite ore and flux (100 g) was quickly added onto the surface of the pre-melted iron bath and maintained for 1 h. Slag samples were collected at defined time intervals (5,7,10,15,20,30 and 60 min) using a steel rod dipped into the slag layer. The samples were quenched rapidly by flushing with high-purity (99.999%) Ar gas (flow rate of 25 L/min).…”

Section: Methodsmentioning

confidence: 99%

Improving the production efficiency of high-titania slag in Ti extraction process: fluxing effect on formation of pseudobrookite

Kim

Heo

Park

et al. 2020

Sci Rep

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We investigated the carbothermic reduction process of ilmenite ore at 1873 K with flux addition. Without flux, the pseudobrookite phase with a high melting temperature was precipitated during ilmenite smelting. This could be the main reason for decreased reduction of iron in ilmenite. To accelerate reduction of ilmenite, two factors were considered. One is increasing the reduction driving force during smelting. Activity of FeO is the major factor to control reduction in driving force. The other factor is delay in formation of the pseudobrookite phase, a high-melting point precipitation phase. In this system, MgO in ilmenite could be used to form pseudobrookite. To control these factors, in this study, flux agent (i.e., Na 2 o or Sio 2 ) addition was considered. The thermochemical simulation program, factSage TM 7.0 was used to calculate the viscosity of slag and the activity of components as fluxing agents were added. High-temperature experiments using an induction furnace were also conducted to confirm the computational results. To determine the composition of final products, i.e., titanium slag, X-ray fluorescence analysis was executed. As a result of Fe and Ti behaviours in slag, SiO 2 addition showed no significant difference from the slag without flux. However, Fe reduction in ilmenite, i.e. tio 2 -enrichment, was more accelerated when Na 2 O was added. X-ray diffraction, scanning electron microscopic and transmission electron microscopic analyses results also showed that even 1 wt% Na 2 o addition significantly influenced the titanium slag production compared to no flux addition.As titanium has good physical and chemical properties, e.g. excellent strength, corrosion resistance, fatigue resistance, fracture toughness, and high-temperature characteristics, its demand steadily increases 1-5 . The major raw material for titanium extraction is rutile (~95% TiO 2 ), which quickly is being depleted. Therefore, ilmenite (FeTiO 3 , 30-65% TiO 2 ) as a substitutional resource is in the spotlight. There are previous studies about the ilmenite smelting process in conjunction with pre-oxidation treatment, which improves the reactivity of ilmenite 6-13 . After the pre-oxidation treatment, the ilmenite ore is sent to direct leaching or high temperature reduction stages according to the consecutive processes [14][15][16][17][18] .Our group originally investigated the effect of temperature on FeO reduction, i.e., TiO 2 -upgrading, from ilmenite ore from 1723 to 1923 K 13 . Unlike the expectation that the Ti-yield would be greater with higher temperatures, the slag composition in the actual experiment was not significantly changed. One of the reasons is precipitation of pseudobrookite (ps-BR), which is one of the most stable phases with M 3 O 5 stoichiometry. In the position of M, the divalent cations (mainly Fe 2+ , minor Ti 2+ and/or Mg 2+ ) and the trivalent cations (primarily Ti 3+ ) are in balance of valence. Thus, it is normally expressed as [Fe,Ti,Mg] x Ti y O 5 (x + y = 3) formula. Because the melting point of ps-B...

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Section: Methodsmentioning

confidence: 99%

Improving the production efficiency of high-titania slag in Ti extraction process: fluxing effect on formation of pseudobrookite

Kim

Heo

Park

et al. 2020

Sci Rep

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“…3 with high melting points and high densities such as Ti-70Ta, Ti-29Nb-13Ta-4.6Zr and Ti-42Nb [12][13][14]. The high melting points of these alloying elements introduces increased difficulty to the processing of biocompatible Ti alloys and make the alloys more prone to compositional segregation which is detrimental to their mechanical properties and performance [15,16]. Additional post-fabrication processes such as high temperature homogenising heat treatments and/or thermoplastic processing are required to alleviate or eliminate segregation [16] which adds to their expense.…”

Section: Accepted Manuscriptmentioning

confidence: 99%

“…The high melting points of these alloying elements introduces increased difficulty to the processing of biocompatible Ti alloys and make the alloys more prone to compositional segregation which is detrimental to their mechanical properties and performance [15,16]. Additional post-fabrication processes such as high temperature homogenising heat treatments and/or thermoplastic processing are required to alleviate or eliminate segregation [16] which adds to their expense. Therefore, due to the high content of costly alloying elements and difficulty in alloy fabrication, many of the recently developed Ti alloys are not competitive with current commercial Ti alloys [15].…”

Section: Accepted Manuscriptmentioning

confidence: 99%

Microstructure, phase composition and mechanical properties of new, low cost Ti-Mn-Nb alloys for biomedical applications

Ehtemam-Haghighi

Attar

Dargusch

et al. 2019

Journal of Alloys and Compounds

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“…The suppression of continuous a GB is crucial to achieve both high strength and high ductility, especially in precipitation-strengthened metastable b titanium alloys. [21][22][23][24] However, similar to a+b titanium alloys, [22,31] the preferential nucleation and growth of a phase at b grain boundaries during aging makes it difficult to avoid. [22] The most efficient route to alleviate the a GB formation is wrought processing, [32] but this route is not applicable to the promising near-net-shape processing methods, such as additive manufacturing.…”

mentioning

confidence: 99%

The Effect of Heating Rate on Discontinuous Grain Boundary Alpha Formation in a Metastable Beta Titanium Alloy

Gao

Rainforth

2020

Metall Mater Trans A

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Continuous grain boundary α ($$ \alpha_{\text{GB}} $$ α GB ) is often observed in age-hardened metastable β titanium alloys and plays a detrimental role in ductility. In this work, we show that the heating rate to the aging temperature is crucial in determining the extent of $$ \alpha_{\text{GB}} $$ α GB . The extent of $$ \alpha_{\text{GB}} $$ α GB is determined by the extent of formation of isothermal ω at grain boundaries. This new finding is significant for suppressing continuous $$ \alpha_{\text{GB}} $$ α GB formation in aging hardened β titanium alloys.

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Segregation mediated heterogeneous structure in a metastable β titanium alloy with a superior combination of strength and ductility

Cited by 26 publications

References 61 publications

Improving the production efficiency of high-titania slag in Ti extraction process: fluxing effect on formation of pseudobrookite

Improving the production efficiency of high-titania slag in Ti extraction process: fluxing effect on formation of pseudobrookite

Microstructure, phase composition and mechanical properties of new, low cost Ti-Mn-Nb alloys for biomedical applications

The Effect of Heating Rate on Discontinuous Grain Boundary Alpha Formation in a Metastable Beta Titanium Alloy

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