Your search keyword '"REFRACTORY ALLOYS"' showing total 170 results

1. Advancements and Perspectives in Additive Manufacturing of Tungsten Alloys and Composites: Challenges and Solutions.

Author

Zarinejad, Mehrdad, Tong, Yunxiang, Salehi, Mojtaba, Mu, Chengfa, Wang, Nian, Xu, Yonglong, Rimaz, Sajjad, Tian, Lintao, Kuah, Kai Xiang, and Chen, Xiaotong

Subjects

ELECTRON beam furnaces, MELTING points, TRANSITION temperature, THERMAL stresses, THERMAL conductivity

Abstract

This review explores additive manufacturing (AM) for refractory tungsten (W) and its alloys, highlighting the primary challenges and determining factors in the AM of pure W, W alloys and composites. The challenges mainly arise from W's high melting point, low laser absorptivity, high thermal conductivity, high melt viscosity, high oxygen affinity, high ductile-to-brittle transition temperature, and inherent embrittlement, which lead to defects and anomalies in AM-produced parts. This review focuses on both processes and alloying strategies to address the issues related to densification, micro-cracking, and the resultant properties in W-based components. Cracking in additively manufactured W remains a persistent issue due to thermal stress, embrittlement, and oxide formation. Powder characteristics, process parameters, and thermal management strategies are crucial for W densification. Throughout the review, existing knowledge and insights are organized into comprehensive tables, serving as valuable resources for researchers delving deeper into this topic. Future research in W-AM should focus on understanding the interaction between AM process parameters and microstructural and material design. Advances in atomic-level understanding, thermodynamic modeling, and data analytics have the potential to significantly enhance the precision, sustainability, and applicability of W-AM. [ABSTRACT FROM AUTHOR]

Published

2024

2. Effect of hot isostatic pressing on porosity of wire-arc directed energy deposited TZM/NbZr1 bimetallic structure

Author

Gazi Tanvir, Md Abdul Karim, Sainand Jadhav, Saiful Islam, Young-Min Kim, Ho Jin Ryu, and Duck Bong Kim

Subjects

Wire-arc additive manufacturing, hot isostatic pressing, heat treatment, pore recovery, bimetallic structure, refractory alloys, Science, Manufactures, TS1-2301

Abstract

This study evaluates the effectiveness of hot isostatic pressing (HIP) in mitigating porosity in TZM-NbZr1 bimetallic structures fabricated via wire-arc directed energy deposition (DED). Two distinct HIP conditions and a combined HIP and heat treatment (HT) were investigated. The pore area fraction decreased from 4 ± 0.05% in the as-built condition to 3.05 ± 0.02% and 1 ± 0.01% after treatment at 1200°C and 1500°C, respectively. Porosity was further reduced to 0.01 ± 0.005% with HIP at 1800°C followed by HT. Plastic deformation strongly influenced pore size and shape at elevated temperatures, particularly above the recrystallisation temperatures of both alloys. At lower treatment temperature, disparity in material flow around the pores resulted in interconnected micro-cracks or micro-void formation. However, the combined HIP and HT process effectively eliminated both cracks and porosities from the interface altering the pore recovery mechanism from micro-void formation to dynamic recrystallisation. Additionally, enhanced Mo diffusion from TZM to NbZr1 was observed at higher temperature.

Published

2024

3. Compressive vs. tensile yield and fracture toughness behavior of a body-centered cubic refractory high-entropy superalloy Al0.5Nb1.25Ta1.25TiZr at temperatures from ambient to 1200°C

Author

Kumar, Punit, Kim, Sang Jun, Yu, Qin, Ell, Jon, Zhang, Mingwei, Yang, Yang, Kim, Ji Young, Park, Hyung-Ki, Minor, Andrew M, Park, Eun Soo, and Ritchie, Robert O

Subjects

Engineering, Materials Engineering, Multiple principal element alloys, Superalloys, Refractory alloys, High-temperature deformation, Tensile behavior, Intergranular fracture, MSD-General, MSD-Structural Materials, Condensed Matter Physics, Mechanical Engineering, Materials, Materials engineering, Mechanical engineering, Condensed matter physics

Abstract

The microstructure of high-entropy alloys with refractory elements and Al as constituents can be considered to be analogous to superalloys. These so-termed refractory high-entropy superalloys (RHSAs) can show remarkable compressive strength up to temperatures exceeding 1200 °C. Here, we examine the microstructure and properties - compressive, tensile, and fracture toughness - of a precipitation-hardened, body-centered cubic, RHSA, Al0.5Nb1.25Ta1.25TiZr, at ambient temperature (RT) to 1200 °C. Two dual-phase microstructures comprising ordered B2 (brittle) and disordered A2 (ductile) phases were produced in this alloy - one with B2 as the matrix, the other with A2 - for evaluation of the mechanical properties. Under compression, both microstructures display RT compressive strengths above 1.5 GPa and considerable ductility exceeding 40% at elevated temperatures; the alloy with the A2 matrix has ∼15% compressive ductility even at RT. However, properties are very different under tensile loading; at all temperatures, both microstructures fail predominately in an intergranular mode in the elastic regime at a fracture stress less than 200 MPa and ductility below 0.15%. The microstructure with the A2 matrix has a KIc fracture toughness of ∼15 MPa√m at RT, although at all temperatures above 800 °C, measured KIc values for both dual-phase microstructures are less than 5 MPa√m. In this study, we investigate the microstructural origin of these mechanical properties, and emphasize the importance of evaluating these alloys in tension.

Published

2023

4. Developing MAX phases for nuclear fusion

Author

Rigby-Bell, Maxwell, Frankel, Philipp, and Haigh, Sarah

Subjects

radiation damage, SAED, STEM, HRDIC, Proton irradiation, Strain, Al, Solid solution, Refractory alloys, 312, Ta, Ti, TEM, Crystallography, FIB, Quaternary alloys, SEM, MAX phases, Nuclear fusion, Shielding, EDS, Materials science, Sintering, Armour, Cold press, Ceramics, Metallo-ceramics, Cermets, DFT, XRD, High temperature pressure-less synthesis

Abstract

The search for high heat flux and radiation resistant component materials remains one of the most stubborn obstacles to the realisation of nuclear fusion as a terrestrial power source. A group of promising materials is the Mn+1AXn (MAX) phases, where 'M' is generally an early transition metal or lanthanide, 'A' is a group 13-15 element, 'X' is carbon or nitrogen, and 'n' is a positive integer. Their interesting mix of properties has led to their consideration as candidates for extreme environment applications, such as in fusion devices. However, whilst some MAX phases have shown promise in certain areas like irradiation-induced amorphisation resistance, others have shown susceptibility to issues such as corrosion and mechanical failure. Nevertheless, given the vast elemental parameter space in which MAX phases exist and the relatively sparse data available in the literature on their tolerance to fusion-relevant environments, there is great potential in the field for development towards fusion-relevant applications. This thesis demonstrates the initial stages of a rapid MAX phase development workflow for nuclear fusion applications. This is achieved via a combination of high-throughput computational predictions, high-temperature powder synthesis, advanced X-ray and electron microscopy characterisation techniques, and high energy ion radiation damage assessments. The relative thermodynamic stabilities of hundreds of potential MAX phases have been calculated using density functional theory (DFT), with the results used to guide high temperature pressure-less sintering trials of promising candidates. As such, a series of novel (Ta,Ti)3AlC2 MAX phases have been synthesised, with crystallographic and elemental characterisations from the atomic to the macroscale performed using X-ray diffraction (XRD) and a suite of high-resolution electron microscopy techniques, such as energy dispersive X-ray spectroscopy (EDS). Finally, the response of Ti3AlC2 and the newly synthesised (Ta0.25Ti0.75)3Al0.77C2 and (Ta0.38Ti0.62)Al0.81C2 MAX phases to extreme nuclear environments has been assessed using high-energy proton irradiations at a range of temperatures up to ~650 °C, with subsequent crystallographic and microstructural evolution quantified in unprecedented detail using XRD, high-resolution digital image correlation (HRDIC) and scanning electron microscopy (SEM). A comparison of the radiation damage tolerance of the three materials is given, with implications for the applicability of Ti-Ta-alloy MAX phases in future nuclear environments, as well as the suitability of proton irradiation in simulating reactor-relevant neutron radiation damage.

Published

2022

5. Advancements and Perspectives in Additive Manufacturing of Tungsten Alloys and Composites: Challenges and Solutions

Author

Mehrdad Zarinejad, Yunxiang Tong, Mojtaba Salehi, Chengfa Mu, Nian Wang, Yonglong Xu, Sajjad Rimaz, Lintao Tian, Kai Xiang Kuah, and Xiaotong Chen

Subjects

refractory alloys, tungsten alloys and composites, additive manufacturing, laser and electron beam melting, challenges and mitigation strategies, Crystallography, QD901-999

Abstract

This review explores additive manufacturing (AM) for refractory tungsten (W) and its alloys, highlighting the primary challenges and determining factors in the AM of pure W, W alloys and composites. The challenges mainly arise from W’s high melting point, low laser absorptivity, high thermal conductivity, high melt viscosity, high oxygen affinity, high ductile-to-brittle transition temperature, and inherent embrittlement, which lead to defects and anomalies in AM-produced parts. This review focuses on both processes and alloying strategies to address the issues related to densification, micro-cracking, and the resultant properties in W-based components. Cracking in additively manufactured W remains a persistent issue due to thermal stress, embrittlement, and oxide formation. Powder characteristics, process parameters, and thermal management strategies are crucial for W densification. Throughout the review, existing knowledge and insights are organized into comprehensive tables, serving as valuable resources for researchers delving deeper into this topic. Future research in W-AM should focus on understanding the interaction between AM process parameters and microstructural and material design. Advances in atomic-level understanding, thermodynamic modeling, and data analytics have the potential to significantly enhance the precision, sustainability, and applicability of W-AM.

Published

2024

6. Rapid screening of single phase refractory alloys under laser melting conditions

Author

Kaitlyn M. Mullin, Carolina Frey, James Lamb, Sophia K. Wu, McLean P. Echlin, and Tresa M. Pollock

Subjects

Refractory alloys, Multi-principal element alloy, High entropy alloy, Additive manufacturing, Solidification cracking, Solid-state cracking, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Refractory alloys can be difficult to fabricate by laser-based manufacturing methods due to their high melting temperatures, high interstitial solubility, and propensity for low temperature brittleness. Laser-based processes, such as welding and additive manufacturing (AM), yield similar populations of defects, including microsegregation and solidification and solid-state cracking. Given the extreme challenges and cost associated with the production of refractory powders, this research aimed to develop a rapid screening methodology that combines predictive defect formation metrics with single track melting experiments. A flexible single laser track melting platform was designed to perform screening experiments on conventional and multi-principal element refractory alloys across a wide range of laser energy inputs. The platform was employed to investigate laser melting on solid substrates, or on a substrate with a single layer of powder feedstock, and is demonstrated with the highly fabricable Nb-base alloy C103. Preliminary investigations are performed on refractory multi-principal element alloys in the Hf-Mo-Nb-Ta-Ti family, and significant differences in cracking resistance and solidification morphology are observed. Implications for future alloy design and processing strategies for defect-resistant refractory alloys for AM are discussed.

Published

2024

7. W-Ni-Fe Refractory Alloy Sintered by Hot Oscillating Pressure Under Different Amplitudes.

Author

Ka Gao, Junliang Zhao, Dejian Sun, Yang Gao, and Linan An

Subjects

PARTICLE size distribution, ALLOYS, SPECIFIC gravity, CORROSION resistance

Abstract

Hot oscillating pressure (HOP) at different amplitudes (0, 5, and 10 MPa) is used to create a tungsten refractory alloy with narrow grain size distribution, higher hardness, and excellent corrosion resistance. The relative density and properties of sintered alloys are significantly improved and enhanced through the amplitude applied. The highest relative density about 99.2% with the narrowest average thickness bonding phase is presented in 10 MPa amplitude alloy. And its average grain size is only 3.67 µm, with a grain growth rate that is only 1.12 × 10-15 m²s-1 slower than that without the amplitude alloy (0 MPa amplitude alloy). Then the excellent hardness (454.7 HV0.5) is obtained. More importantly, the corrosion current of 10 MPa amplitude alloy is only just 5.09 × 10-6A cm-2 and reduces by nearly 9% compared with 0 MPa amplitude alloy. The hardness and corrosion resistance are better than those of other similar materials ever reported. The above results show that the HOP with amplitudes has a positive effect on improving the densification, hardness, corrosion resistance, and inhibiting the growth of grain size. [ABSTRACT FROM AUTHOR]

Published

2023

8. Degradation of the mechanical properties of NbMoTaW refractory high-entropy alloy in tension.

Author

Kumar, Punit, Gou, Xueqian, Cook, David H., Payne, Madelyn I., Morrison, Nathaniel J., Wang, Wenqing, Zhang, Mingwei, Asta, Mark, Minor, Andrew M., Cao, Ruqing, Li, Yi, and Ritchie, Robert O.

Subjects

*FRACTURE strength, *FRACTURE toughness, *TENSILE strength, *METAL microstructure, *MICROSTRUCTURE

Abstract

The mechanical properties of the bcc refractory high-entropy alloy (RHEA) NbMoTaW with columnar and equiaxed microstructures and a nanoscale metal oxide layer on the grain boundaries are investigated at ambient temperatures (RT) to 1200 °C. Under compression, the alloy shows a yield strength, σ y , of ⁓1390 ± 20 MPa at RT and retains a high yield strength, σ y , of ⁓301.5 MPa at 1200 °C. However, in tension, the fracture strengths, σ f , of both columnar and equiaxed microstructures are far lower - below 70 MPa - and the material fails in the elastic regime without showing any measurable ductility at all temperatures. The fracture mechanisms in tension transition from transgranular cleavage at RT to a mixture of transgranular and intergranular fracture at 800 °C to a complete intergranular fracture at 1200 °C due to selective weakening of the metal oxide layer on the grain boundaries driven by a structural change. The transition in the fracture mechanism in the equiaxed microstructure promotes extrinsic toughening at higher temperatures, resulting in a ⁓6.4 times higher fracture toughness (K Ic ⁓10.3 MPa√m) at 1200 °C compared to that at RT. NbMoTaW is a well-known RHEA, but the poor tensile strength and fracture toughness measured in this study highlight the critical importance of investigating the mechanical properties of these high-temperature RHEAs in tension. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

9. Nanoscale structure damage in irradiated W-Ta alloys for nuclear fusion reactors

Author

Ipatova, Iuliia, Preuss, Michael, Pimblott, Simon, and Jimenez-Melero, Enrique

Subjects

620, Refractory alloys, Electron microscopy, Fusion energy, Nuclear reactors, Radiation damage

Abstract

In this project, we have assessed the structural tolerance of advanced refractory alloys to simulated nuclear fusion reactor environments, by using intense proton beams to mimic fusion neutron damage and analysing the proton damaged structures using in-situ/ex-situ transmission electron microscopy and nano-hardness measurements. Refractory metals such as tungsten or tantalum, and their binary alloy combinations, are considered as promising structural materials to withstand the unprecedented high heat loads and fast neutron/helium fluxes expected in future magnetically-confined fusion reactors. Tungsten is currently the frontrunner for the production of plasma-facing components for fusion reactors. The attractiveness of tungsten as structural material lies in its high resistance to plasma-induced sputtering, erosion and radiation-induced void swelling, together with its thermal conductivity and high-temperature strength. Unfortunately, the brittle nature of tungsten hampers the manufacture of reactor components and can also lead to catastrophic failure during reactor operations. We have focused on two potential routes to enhance the ductility of tungsten-containing materials, namely alloying tungsten with controlled amounts of tantalum, and using alternatively tantalum-based alloys containing specific tungsten additions, either as a full-thickness structural facing material or as a coating of first wall reactor components. The aim was to investigate the formation and evolution of radiation-induced damaged structures in these material solutions and the impact of those structures on the hardness of the material. The main results of this work are: (1) the addition of 5wt%Ta to W leads to saturation in the number density and average dimensions of the radiation-induced a/2 dislocation loops formed at 350C, whereas in W the loop length increases progressively and evolves into dislocation strings, and later into hydrogen bubbles and surface blisters, (2) the recovery behaviour of proton irradiated W5wt.%Ta alloy is characterized by dislocation loop growth at 600-900C, whereas voids form at 1000C by either vacancy absorption or loop collapse, (3) the presence of radiation-induced a loops at 590C in Ta hinders the formation and ordering of voids observed with increasing damage levels at 345C, (4) the addition of 5-10wt.%W to Ta delays the evolution of a/2 dislocation loops with increasing damage levels, and therefore the appearance of random voids. These results expand the composition palette available for the safe selection of refractory alloys for plasma facing components with enhanced, or at least predictable, tolerance to the heat-radiation flux combinations expected in future nuclear fusion plants.

Published

2018

10. Design of BCC refractory multi-principal element alloys with superior mechanical properties

Author

Weiji Lai, Florian Vogel, Xueyang Zhao, Binbin Wang, Yanliang Yi, Deqiang You, Xin Tong, Wei Li, Xiang Yu, and Xiaojian Wang

Subjects

refractory alloys, strength and ductility, lattice distortion, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

The correlations between tensile properties and some common parameters in BCC refractory multi-principal element alloys (RMPEAs) have been systematically investigated. The findings can be used as guidelines for the alloy design. We found that there exists a positive linear correlation between average atomic shear modulus mismatch and yield strength, and more negative enthalpy of mixing is peculiarly prone to brittle fracture in RMPEAs. Meanwhile, some BCC RMPEAs with first-class tensile properties were designed successfully. The analyses of alloys’ toughen mechanism revealed that their high strength, as well as good ductility, is attributed to lattice distortion and dislocation glide respectively.

Published

2022

11. Creep Behavior of Additively Manufactured, Oxide Dispersion Strengthened, and Refractory Multi-Principal Element Alloys

Author

Sahragard-Monfared, Gianmarco

Subjects

Materials Science, Engineering, Mechanical engineering, Additive manufacturing, Creep, Multi-principal element alloys, Oxide dispersion strenghening, Refractory alloys

Abstract

This study investigates the influence of processing methods and oxide dispersion strengthening (ODS) on the creep behavior and deformation mechanisms of several multi-principal element alloys (MPEA). The effect of a BCC crystal structure composed of refractory elements on the creep behavior of MPEAs is also investigated. The materials examined are equiatomic wrought and additively manufactured (AM) CrCoNi, equiatomic AM ODS CrCoNi, and wrought Nb45Ta25Ti15Hf15. Constant stress creep tests were performed on all materials to determine stress exponents and activation energies. Stress reduction creep tests were conducted on AM CrCoNi and AM ODS CrCoNi to characterize activation areas and subsequently their rate-controlling deformation mechanisms during steady state creep. Scanning electron microscopy (SEM) was utilized to characterize initial microstructures, atomic compositions, and fracture surfaces. Pre- and post-creep dislocation structures were characterized by transmission electron microscopy (TEM). Stress exponents of 4.5 ± 0.2, 5.9 ± 0.1, 6.5 ± 0.1 were determined for wrought CrCoNi, AM CrCoNi, and AM ODS CrCoNi, respectively. These results indicate that the stress dependence of the creep behavior is different for each of these FCC MPEAs and thus they have unique creep deformation mechanisms. Activation energy ranges of 240 – 259 kJ/mol, 320 – 331 kJ/mol, and 335 – 367 kJ/mol were found for wrought CrCoNi, AM CrCoNi, and AM ODS CrCoNi, respectively. The increasing activation energy ranges reflect the improved temperature resistance of these FCC alloys. The Nb45Ta25Ti15Hf15 exhibited creep properties superior to the investigated FCC MPEAs at all but the lowest values of applied stress, with its creep deformation behavior being attributed to thermally activated and stress assisted dislocation glide.The AM material exhibited superior creep resistance and inferior creep ductility compared to wrought alloy. This difference was attributed to the AM material having a higher percentage of Cr-rich oxides and a lower percentage of low angle grain boundaries (LAGB). Three types of Cr-rich oxides were observed via TEM/STEM-EDS in the AM material, leading to dislocation interactions with these oxide particles as well as contributing to the nucleation of voids leading to fracture. Essentially no oxides were found in the wrought material. The AM material has a lower LAGB density than the wrought material, leading to fewer dislocation pile-up stress concentrations in the wrought material due to the propensity to propagate deformation more readily through LAGBs. The steady state dislocation structures of the AM and wrought material consist of individual curved dislocations with dislocation multijunctions and jogs.Compared to its non-ODS counterpart, AM ODS CrCoNi has superior creep resistance at all tested stresses and temperatures. The excellent creep resistance of AM ODS CrCoNi was attributed to the interaction of mixed character dislocations with oxide particles. The creep ductility of AM ODS CrCoNi was higher than its non-ODS counterpart due to a large percentage of low angle grain boundaries associated with its columnar grain structure. It was also found that creep ductility is significantly greater at the highest applied stress of 200 MPa compared to lower stresses. The steady state dislocation structure of AM ODS CrCoNi consists of long arrays of dislocations which is different than that observed in non-ODS CrCoNi which consists of individual curved dislocations.Operational activation areas were determined to be 920 b2 for AM ODS CrCoNi and 960 b2 for AM CrCoNi. These operational activation areas are indicative of forest dislocation controlled steady state creep, which is consistent with the dislocation structures observed in these alloys. The operational activation area of AM CrCoNi is significantly higher than the values reported for CrMnFeCoNi, revealing a difference in rate controlling mechanism. The quinary alloy is rate limited by a combination of dislocation interactions with forest dislocations and the solid solution matrix, and the simplified ternary alloy is controlled solely by forest dislocation strengthening. Similarly, the operational activation area of AM ODS CrCoNi is significantly higher than the values reported for other ODS alloys, indicating that the volume fraction of oxides in AM ODS CrCoNi is too low to effectively limit the rate of dislocation motion, and revealing that the thermal activation of dislocation glide is instead limited by forest dislocations.Creep behavior in Nb45Ta25Ti15Hf15 was characterized by both the power law creep model and the thermally activated dislocation glide model. Utilizing the power law creep model, a stress exponent of 1.2 was measured at low applied stresses suggesting diffusion controlled creep occurs in this regime. A stress exponent of 5.7 was measured at high applied stresses implying dislocation climb controlled creep in the high stress regime. However, an exponential relationship provides a better fit of the creep data, suggesting that the conventional phenomenological power law approach does not accurately describe the creep behavior in this material. The exponential approach is consistent with the thermally activated and stress assisted dislocation glide description of the rate controlling mechanism for creep deformation in Nb45Ta25Ti15Hf15. Brittle intergranular fracture was observed as a result of Hf-oxide formation at grain boundaries. This brittle intergranular fracture decreased creep ductility, creep life, and creep rate, especially at low applied stresses where extended exposure to oxygen resulted in more extensive brittle intergranular fracture.

Published

2023

12. Angular-dependent interatomic potential for large-scale atomistic simulation of W-Mo-Nb ternary alloys

Author

Starikov, Sergei, Grigorev, Petr, Olsson, Pär A T, Starikov, Sergei, Grigorev, Petr, and Olsson, Pär A T

Abstract

We present a new classical interatomic potential designed for simulation of the W-Mo-Nb system. The angular-dependent format of the potential allows for reproduction of many important properties of pure metals and complex concentrated alloys with good accuracy. Special attention during the development and validation of the potential was paid to the description of vacancies, screw dislocations and planar defects, as well as thermo-mechanical properties. Here, the applicability of the developed model is demonstrated by studying the temperature dependence of the elastic moduli and average atomic displacement in pure metals and concentrated alloys up to the melting point.

Published

2024

13. Revealing the critical role of vanadium in radiation damage of tungsten-based alloys.

Author

Wei, Guanying, Byggmästar, Jesper, Cui, Junzhi, Nordlund, Kai, Ren, Jingli, and Djurabekova, Flyura

Subjects

*RADIATION damage, *TUNGSTEN, *DISLOCATION loops, *VANADIUM, *LEAD alloys, *ALLOYS, *RADIATION tolerance

Abstract

Refractory tungsten-based medium- and high-entropy alloys form a promising class of strong, heat- and radiation-resistant materials for nuclear applications. Here, we systematically explore the radiation tolerance of Mo–Nb–Ta–V–W alloys using molecular dynamics simulations and a machine-learned interatomic potential. Going from pure W to W-based equiatomic binaries, ternaries, quaternary, and the quinary high-entropy alloy, we simulate the radiation damage accumulation up to 0.4–0.8 dpa through cumulative collision cascades. We find that the radiation damage and evolution are controlled by a combination of cascade-induced clustering, the balance in migration of vacancies and interstitials, and defect cluster binding energies. These mechanisms are strongly influenced by atom size, among which vanadium as the smallest atom is decisive. In pure W and alloys without V, the microstructure is characterised by large and growing interstitial dislocation loops. In stark contrast, in alloys containing V, vacancy dislocation loops are formed directly in collision cascades and the balanced migration rate of vacancies and interstitials promotes recombination and prevents growth of interstitial loops. The atom size differences also lead to clear segregation, with small atoms (V) in interstitial clusters and larger atoms (Ta, Nb) segregating around vacancy clusters. Furthermore, the small cluster sizes, formation of vacancy loops, segregation, and balanced migration in V-containing alloys lead to low swelling and an exceptionally efficient defect annealing compared to pure W and V-free alloys. Our results highlight WTaV as a promising low-activation material, where almost 90% of defects are annealed at 2000 K during 5 ns compared to < 20 % in pure W. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

14. Synthesis of Refractory High-Entropy Alloy WTaMoNbV by Powder Bed Fusion Process Using Mixed Elemental Alloying Powder.

Author

Ron, Tomer, Leon, Avi, Popov, Vladimir, Strokin, Evgeny, Eliezer, Dan, Shirizly, Amnon, and Aghion, Eli

Subjects

*ALLOY powders, *CONSTRUCTION materials, *RAW materials, *ARC furnaces, *TRANSMISSION electron microscopy, *SCANNING electron microscopy

Abstract

The growing interest in refractory high-entropy alloys (HEAs) in the last decade is mainly due to their thermal stability, outstanding mechanical properties, and excellent corrosion resistance. However, currently HEAs are still not considered for use as common structural materials due to their inherent drawbacks in terms of processing and machining operations. The recent progress witnessed in additive manufacturing (AM) technologies has raised the option of producing complex components made of HEAs with minimal machining processes. So far, this could be achieved by using pre-alloyed powders of HEAs that were mainly produced by a conventional arc melting furnace (AMF) in the form of small compounds that were transformed into powder via a gas atomization process. To significantly reduce the production cost, the present study aims to analyze the ability to synthesize HEA WTaMoNbV via a laser powder bed fusion (LPBF) process using mixed elemental alloying powder as the raw material. For comparison, a counterpart alloy with the same chemical composition was analyzed and produced by an AMF process. The microstructures of the tested alloys were examined by scanning electron microscopy (SEM), transmission electron microscopy (TEM) and X-ray diffraction (XRD) analyses. The physical properties were evaluated in terms of density and mechanical strength, while the electrochemical behavior was assessed by potentiodynamic polarization analysis. The results disclosed similarities in microstructure, physical properties and electrochemical behavior between HEA WTaMoNbV manufactured by the proposed LPBF process and its counterpart alloy produced by an AMF process. [ABSTRACT FROM AUTHOR]

Published

2022

15. Design of BCC refractory multi-principal element alloys with superior mechanical properties.

Author

Lai, Weiji, Vogel, Florian, Zhao, Xueyang, Wang, Binbin, Yi, Yanliang, You, Deqiang, Tong, Xin, Li, Wei, Yu, Xiang, and Wang, Xiaojian

Subjects

MECHANICAL alloying, MODULUS of rigidity, BRITTLE fractures, REFRACTORY materials, ALLOY analysis, LIQUID alloys

Abstract

The correlations between tensile properties and some common parameters in BCC refractory multi-principal element alloys (RMPEAs) have been systematically investigated. The findings can be used as guidelines for the alloy design. We found that there exists a positive linear correlation between average atomic shear modulus mismatch and yield strength, and more negative enthalpy of mixing is peculiarly prone to brittle fracture in RMPEAs. Meanwhile, some BCC RMPEAs with first-class tensile properties were designed successfully. The analyses of alloys' toughen mechanism revealed that their high strength, as well as good ductility, is attributed to lattice distortion and dislocation glide respectively. This work provided some effective guidelines for the design of BCC refractory multi-principal element alloys with superior strength-ductility combinations via utilizing several common physical parameters. [ABSTRACT FROM AUTHOR]

Published

2022

16. On the chemical and microstructural requirements for the pesting-resistance of Mo–Si–Ti alloys

Author

Susanne Obert, Alexander Kauffmann, Sascha Seils, Steven Schellert, Matthias Weber, Bronislava Gorr, Hans-Jürgen Christ, and Martin Heilmaier

Subjects

High temperature materials, Scanning electron microscopy, Refractory alloys, Transmission electron microscopy, High temperature corrosion, Oxidation resistance, Mining engineering. Metallurgy, TN1-997

Abstract

In recent publications [Schliephake et al. in Intermetallics 104 (2019) 133–142 and Obert, Kauffmann & Heilmaier in Acta Materialia, 184 (2020) 132–142], an unexpected pesting-stability of fully eutectic and specific eutectic–eutectoid Mo–Si–Ti alloys was found. Several potential reasons were proposed: microstructural length scale being typically very fine due to the eutectic and eutectoid reactions, the phase distribution including the fraction of the eutectic and eutectoid regions, as well as the chemical composition of the individual phases. In the present study, we prove the Ti content to be decisive for the pesting-resistance in air at 800 °C by investigating the microstructure and oxidation behaviour of Mo–Si–Ti alloys with systematically varying nominal Ti content. A critical Ti content of 43 at% was identified. Due to the phase equilibrium, this corresponds to a local Ti content in Mo solid solution of 35 at%. Other microstructural properties such as (i) lamellar size within eutectic and eutectoid regions and (ii) volume fraction of the eutectic and eutectoid regions were demonstrated to have an insignificant influence on the pesting-resistance of the alloys. Rather, the assessment of the oxidation behaviour of the monolithic phase MoSS, which was identified to be crucial for the oxidation behaviour of the Mo–Si–Ti alloys, confirmed an improvement in oxidation behaviour with increasing Ti content.

Published

2020

17. Hypercooling limit and physical properties of liquid MoNbReTaW refractory high-entropy alloy.

Author

Hu, L., Lin, M. J., and Wei, B.

Subjects

*GIBBS' free energy, *EXPANSION of liquids, *SUPERCOOLED liquids, *LATENT heat of fusion, *LIQUIDUS temperature, *SPECIFIC heat, *LIQUID alloys

Abstract

The thermophysical properties of refractory MoNbReTaW high-entropy alloy in both supercooled liquid and high-temperature solid states were explored by an electrostatic levitation technique. The maximum supercooling attains 504 K, and the hypercooling limit is derived as 571 K. The liquid density at liquidus temperature is measured to be 13.3 g cm−3, which increases linearly with decreasing temperature at a slope of 6.83 × 10−4 g cm−3 K−1. The liquid alloy exhibits 5.3% relative volume shrinkage during crystallization. The thermal expansion coefficient of liquid and solid alloy at liquidus temperature are determined as 5.0 × 10−5 K−1 and 3.6 ×10−5 K−1, respectively. The liquid specific heat at liquidus temperature is found to be 38.2 J mol−1 K−1, and basically displays a linear decreasing tendency with temperature. According to the calculated enthalpy of fusion 24.7 kJ mol−1 and measured specific heats, the temperature-dependent entropy and Gibbs free energy difference between supercooled liquid and crystalline solid are obtained. [ABSTRACT FROM AUTHOR]

Published

2021

18. Soldering Methods for Preparing Permanent Joints of Ceramic Composite Materials with Metals (Review Article).

Author

Kulik, V. I., Nilov, A. S., Bogachev, E. A., and Larionov, N. V.

Subjects

*CERAMIC materials, *METALLIC composites, *SOLDER & soldering, *LIQUID metals, *MANUFACTURING processes, *TIN alloys, *COPPER-tin alloys, *COMPOSITE materials

Abstract

Use of soldering methods for preparing high-temperature permanent joints of silicon carbide ceramic matrix composites (CMC) with metals is analyzed. The main problems in joining CMC with metals are considered associated with poor wettability of CMC with molten metals, a significant difference in the LTEC of CMC and metals, and formation of substances with high hardness and brittleness within a connecting layer. Analysis of practical experience of using traditional and diffusion soldering methods for joining CMC of the Cf/SiC type with metal alloys based on Ni, Nb, Ti, Mo, and stainless steel is provided. The most typical solder compositions and soldering process production methods are considered. It is shown that these technologies make it possible to create reliable and strong joints for CMC components and various metals. [ABSTRACT FROM AUTHOR]

Published

2021

19. Stability of the B2 phase in refractory high entropy alloys containing aluminum.

Author

Brodie, Julian, Wang, Junxin, Couzinié, Jean-Philippe, Heczko, Milan, Mazánová, Veronika, Mills, Michael J., and Ghazisaeidi, Maryam

Subjects

*ALUMINUM alloys, *ANTISITE defects, *ALUMINUM alloying, *ENTROPY, *REFRACTORY materials, *ALLOYS

Abstract

We study the phase stability of the B2 phase in a two-phase Al 0. 5 NbTa 0. 8 Ti 1. 5 V 0. 2 Zr refractory high entropy alloy. We find that the ordered phase of this alloy primarily contains Zr, Al, and Ti, where Zr and Al occupy opposite sublattices. Although the site occupancy of Ti is not conclusive from the experiments, first-principles calculations confirm the preference of Ti atoms to occupy the Zr sublattice. We also find that the B2 phase composed of Al, Zr, and Ti is unstable and that it transforms into Zr 5 Al 4 Omega, L 1 0 , or an ordered hexagonal phase depending on strain and the presence of antisite defects. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

20. Neural network for predicting Peierls barrier spectrum and its influence on dislocation motion.

Author

Wang, Xinyi, Valdevit, Lorenzo, and Cao, Penghui

Subjects

*BINARY metallic systems, *GEOGRAPHICAL discoveries, *SCREW dislocations, *ATOMIC displacements, *TERNARY system

Abstract

The Peierls barrier represents the inherent lattice resistance to dislocation glide, controlling dislocation movement and dictating the resulting mechanical properties. The rise of multi-principal element alloys, with their vast compositional space and local chemical fluctuations, introduces notable challenges in efficiently computing the Peierls barriers. Here, we propose a neural network model that captures the chemistry and structure of screw dislocations. By incorporating two crucial inputs, the local atomic type and displacement, our model enables accurate and efficient prediction of the Peierls barriers in multi-component space. Using this neural network, we construct a barrier diagram across the entire ternary space of refractory Nb-Mo-Ta alloys, from which the compositions with high or low barriers can be quickly identified. We discover that the NbMo binary alloy can have a higher barrier than NbMoTa ternary system, suggesting chemical complexity may not be the predominant factor governing dislocation barrier. Subsequently, three screened compositions with different barriers are selected for studying their effects on dislocation motion. Atomistic simulations reveal that a higher mean barrier slows down dislocation mobility, while a broader distribution of barriers facilitates kink pair nucleation, altering the rate-limiting process from kink pair nucleation to kink glide and cross kinking. This study presents a general neural network model that enables rapid screening composition with the desired barrier spectrum and will impact the exploration and discovery of alloys with improved dislocation-controlled properties. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

21. Post-irradiation examination of commercial tantalum alloys following neutron irradiation.

Author

Massey, Caleb P., Goetz, Callie K., Lin, Yan-Ru, Werden, Jesse, Curlin, Stephanie, Siggillino, Thomas I., Zinkle, Steven J., and Busby, Jeremy T.

Subjects

*NEUTRON irradiation, *TANTALUM alloys, *DISLOCATION loops, *SCANNING transmission electron microscopy, *ENERGY dispersive X-ray spectroscopy, *HIGH temperatures

Abstract

Post irradiation examination of two commercial tantalum alloys (based on Ta-8 %W) revealed significant irradiation hardening following neutron irradiation in the High Flux Isotope Reactor at Oak Ridge National Laboratory. Tensile samples of commercial Ta alloys T-111 and ASTAR-811C were irradiated to a total neutron fluence (E > 0.1 MeV) in the range (2–4)x1021 n/cm2 (0.39–0.75 dpa) at an irradiation temperature near 900 °C. Tensile testing conducted at room temperature and at 800 °C revealed significant irradiation hardening under all test conditions. Samples that were tensile tested at room temperature exhibited brittle failure, whereas ductility was maintained for elevated temperature testing. The irradiation hardening and embrittlement noted for both alloys was attributed to irradiation-induced dislocation loop formation as confirmed through scanning transmission electron microscopy analysis. Corresponding energy dispersive x-ray spectroscopy revealed radiation-induced segregation of Hf in these loop populations. This Hf enrichment is shown to result in eventual co-precipitation of elongated (Hf,O)-rich precipitates along the dislocation loops. These results show that irradiation hardening is enhanced via irradiation-enhanced precipitation at elevated irradiation temperatures. Consequently, the minimum recommended operating temperature window for Ta alloys should be increased to account for observed hardening/embrittlement at irradiation temperatures as high as 900 °C (1,173 K). [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

22. Niobium and Other High Temperature Refractory Metals for Aerospace Applications

Author

Satya Prasad, V. V., Baligidad, R. G., Gokhale, Amol A., Raj, Baldev, Editor-in-chief, Mudali, U. Kamachi, Editor-in-chief, Prasad, N. Eswara, editor, and Wanhill, R. J. H., editor

Published

2017

23. Effect of oxidation on the thermal expansion of a refractory multicomponent alloy.

Author

Osei-Agyemang, Eric and Balasubramanian, Ganesh

Subjects

*THERMAL expansion, *ALLOYS, *METALWORK, *LATTICE constants, *OXIDATION

Abstract

We employ first-principles calculations to examine the role of oxidation on the thermal expansion behaviour of a refractory multicomponent alloy. Our results reveal that the linear expansion and the coefficient of volumetric expansion over a range of temperatures have higher values for the oxidised alloy than the pure material. The enhanced expansion for the oxidised alloy is attributed to significant changes in the lattice parameter of the alloy upon surface oxidation. During oxidation, the diffusion of oxygen atoms to the subsurface layer of the alloy after complete surface coverage produces a displacement of the constituent elements that form metal oxides. This depletion creates vacancy sites in the lattice for enabling enhanced expansivity in the oxidised structure relative to the pure refractory alloy. [ABSTRACT FROM AUTHOR]

Published

2021

24. Freezing Shrinkage Dynamics and Surface Dendritic Growth of Floating Refractory Alloy Droplets in Outer Space.

Author

Wang H, Liao H, Hu L, Zheng C, Chang J, Liu D, Li M, Zhao J, Xie W, and Wei B

Abstract

The freezing shrinkage and dendritic growth are of great importance for various alloys solidified from high-temperature liquids to solids since they dominate microstructure patterns and follow-up processing. However, the microgravity freezing shrinkage dynamics is scarcely explored on the ground as it is hard to suppress the strong natural convection inside liquid alloys. Here, a series of in-orbit solidification experiments is conducted aboard the China Space Station with a long-term stable 10 -5 g 0 microgravity condition. The highest temperature up to 2265 K together with substantial liquid undercoolings far from a thermodynamically stable state are attained for both Nb 82.7 Si 17.3 and Zr 64 V 36 refractory alloys. Furthermore, the solidification under microgravity of a droplet is simulated to reveal the liquid-solid interface migration, temperature gradient, and flow field. The microgravity solidification process leads to freezing shrinkage cavities and distinctive surface dendritic microstructure patterns. The combined effects of shrinkage dynamics and liquid surface flow in outer space result in the dendrites growing not only along the tangential direction but also along the normal direction to the droplet surface. These space experimental results contribute to a further understanding of the solidification behavior of liquid alloys under a weaker convection condition, which is often masked by gravity on the ground., (© 2024 Wiley‐VCH GmbH.)

Published

2024

25. Alloying effect on the oxidation behavior of a ductile Al0.5Cr0.25Nb0.5Ta0.5Ti1.5 refractory high-entropy alloy

Author

S. Sheikh, L. Gan, A. Ikeda, H. Murakami, and S. Guo

Subjects

Refractory alloys, High-entropy alloys, Ductility, Oxides, Nitrides, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Refractory high-entropy alloys (RHEAs) are widely studied because of their promising potential for ultrahigh-temperature applications. One key challenge towards the development of RHEAs as high-temperature structural materials is to concurrently achieve optimum oxidation resistance and mechanical properties. Here in this work, the effect of alloying on the oxidation behavior of ductile RHEAs was studied. Specifically, a ductile RHEA, Al0.5Cr0.25Nb0.5Ta0.5Ti1.5, was alloyed with Al and Zr aiming to improve its oxidation resistance. The two modified RHEAs, Al0.75Cr0.25Nb0.5Ta0.5Ti1.5 and Al0.5Cr0.25Nb0.5Ta0.5Ti1.5Zr0.01, indeed show enhanced oxidation resistance at 800 °C and 1,100 °C, compared with Al0.5Cr0.25Nb0.5Ta0.5Ti1.5. In addition, all three RHEAs studied here show an excellent oxidation resistance at 800 °C compared with other RHEAs, although there is still a large space to further improve their performance at 1,100 °C. Internal oxidation and even nitridation are still present after oxidation exposure, indicating further efforts are required to form protective oxide scales on the surface of ductile RHEAs. Nevertheless, the work is expected to shed some light on future directions of improving the oxidation of ductile RHEAs, via the alloying route.

Published

2020

26. Structure and Phase Composition of Refractory Alloys of the Co – Al – Mo – Nb System.

Author

Davydov, D. I., Kazantseva, N. V., Popov, N. A., Narygina, I. V., and Popova, E. N.

Subjects

*MOLYBDENUM, *ALLOYS, *DIFFERENTIAL scanning calorimetry, *PHASE transitions, *NIOBIUM

Abstract

The structures and phase compositions of a series of refractory alloys of the Co – Al – Mo – Nb system (the cobalt angle) are studied by differential scanning calorimetry (DSC) and scanning microscopy. The effect of the contents of niobium and molybdenum on the phase composition and the temperature boundaries of the range of existence of the Co3(Al, Mo, Nb) intermetallic phase are determined. [ABSTRACT FROM AUTHOR]

Published

2020

27. Phase diagrams of refractory bimetallic nanoalloys.

Author

Mendoza-Pérez, Rafael and Muhl, Stephen

Subjects

*PHASE diagrams, *GIBBS' free energy, *NANOSTRUCTURED materials, *ALLOYS, *REFRACTORY materials, *TETRAHEDRA

Abstract

Nanostructured materials exhibit remarkable properties significantly different from their bulk counterparts. Metal alloys at the nanoscale show an impressive potential to produce new systems having well-designed functionalities. By using a nanothermodynamic approach, here, we present the effects of the size and shape of the nanoparticles (NPs) on the phase diagrams (PDs) of the Mo-M (M = Nb, Ta, and W) alloys. A well-known group of morphologies at 50, 20, and 10 nm in diameter was considered, which are as follows: tetrahedron, cube, octahedron, decahedron, dodecahedron, cuboctahedron, rhombic dodecahedron, sphere, icosahedron, and truncated octahedron. From an examination of the liquidus and solidus curves, we calculated the expansion or contraction of the coexistence solid-liquid region of the PDs and how these changes are related to the size and shape of the NPs. Through a detailed Gibbs free energy (GFE) analysis, we also determined the thermal stability of the three Mo-based nanoalloys as a function of the size (10–50 nm) of the mentioned polyhedra, by fixing the temperature and the chemical composition. Finally, the surface segregated element was predicted in each bimetallic system. Graphical abstract [ABSTRACT FROM AUTHOR]

Published

2020

28. STUDY OF PHASE EQUILIBRIA AND DIFFUSION IN SEVERAL BINARY AND MULTINARY ALLOY SYSTEMS

Author

Wang, Chuangye and Wang, Chuangye

Abstract

This study leveraged the high-throughput experiments and high-throughput calculations to study the thermodynamic and kinetic behaviors, and mechanical properties of different alloy systems. CALculation of PHAse Diagrams (CALPHAD) and machine learning (ML) are two computational approaches to predict the phase equilibria of alloys and were adopted to study the phase formation of 2436 high-entropy alloys (HEAs). HEAs were found to form 100% BCC at VEC < 6.87 and form essentially 100% FCC at VEC > 9.16 experimentally, this is consistent with the CALPHAD calculations (VEC = valence electron concentration). ML trained models can reach more than 90% accuracy in predicting BCC/B2, BCC/B2 + FCC, and FCC phases. An autonomous materials search engine (AMASE) method was developed by collaborators to map the phase diagram of the thin-film Sn-Bi system in a closed-loop method, which speeds up the phase diagram mapping and thermodynamic assessment processes over the traditional grid mapping. In the NSF sponsored project, the diffusion-multiple approach was employed to map the phase diagrams of the ternary subsystems of the Cr-Fe-Ni-Nb system. Wavelength-dispersive spectroscopy (WDS) mapping was adopted to measure the compositions in the triple-junction areas of diffusion multiples, leading to improve the efficiency of constructing phase diagrams in comparison with the previous practice of using electron probe microanalysis (EPMA) line scans. The WDS mapping method was demonstrated in the experimentally determined ternary phase diagram of Fe-Nb-Ni at 1100 °C. The measured tie-line data was then provided to collaborators to obtain more accurate predictions of the phase stability of topologically close-packed (TCP) phases for future improvement of the Ni-based thermodynamic databases. Besides thermodynamic calculations, mobility assessments of 25 binary systems with single-phase BCC or FCC structure were performed using the 1-parameter Z-Z-Z binary diffusion model. The data will be u

Published

2023

29. Bimetallic structure of TZM and NbZr1 fabricated by wire-based directed energy deposition.

Author

Jadhav, Sainand, Abdul Karim, Md, and Bong Kim, Duck

Subjects

*NIOBIUM alloys, *TENSILE strength, *INTERMETALLIC compounds, *MOLYBDENUM alloys, *TENSILE tests, *WIRE

Abstract

• Successful fabrication of TZM-NbZr1 bimetallic structure using wire-based DED. • Fabricated structure did not form any cracks and intermetallic compounds. • Non-uniformly distributed pores in NbZr1 matrix near to TZM-NbZr1 interface. • Ultimate tensile strength of 249 ± 126 MPa with elongation less than 6 % was achieved. The outcome of this study highlights the feasibility of additively manufactured bimetallic structures from refractory alloys for high-temperature applications. Using a wire-based directed energy deposition (DED) process, a bimetallic structure composed of molybdenum alloy (TZM) and niobium alloy (NbZr1) was successfully fabricated. The TZM-NbZr1 interface displayed no significant defects, such as cracks or delamination, and showed no presence of intermetallic compounds. A few pores were observed on the deposited NbZr1 side near the interface. During uniaxial tensile testing, the specimen's failure occurred on the NbZr1 side in close proximity to the interface, resulting in an ultimate tensile strength of 249 ± 126 MPa and an elongation of less than 6 %. [ABSTRACT FROM AUTHOR]

Published

2024

30. Rapid screening of single phase refractory alloys under laser melting conditions.

Author

Mullin, Kaitlyn M., Frey, Carolina, Lamb, James, Wu, Sophia K., Echlin, McLean P., and Pollock, Tresa M.

Subjects

*ALLOYS, *REFRACTORY materials, *MELTING, *SOLID-state lasers, *LASER ranging, *BRITTLENESS

Abstract

Refractory alloys can be difficult to fabricate by laser-based manufacturing methods due to their high melting temperatures, high interstitial solubility, and propensity for low temperature brittleness. Laser-based processes, such as welding and additive manufacturing (AM), yield similar populations of defects, including microsegregation and solidification and solid-state cracking. Given the extreme challenges and cost associated with the production of refractory powders, this research aimed to develop a rapid screening methodology that combines predictive defect formation metrics with single track melting experiments. A flexible single laser track melting platform was designed to perform screening experiments on conventional and multi-principal element refractory alloys across a wide range of laser energy inputs. The platform was employed to investigate laser melting on solid substrates, or on a substrate with a single layer of powder feedstock, and is demonstrated with the highly fabricable Nb-base alloy C103. Preliminary investigations are performed on refractory multi-principal element alloys in the Hf-Mo-Nb-Ta-Ti family, and significant differences in cracking resistance and solidification morphology are observed. Implications for future alloy design and processing strategies for defect-resistant refractory alloys for AM are discussed. • A single track laser set-up was developed for rapid screening of refractory multi-principal element alloys. • Similarities in solidification morphology and defects observed in laser melted C103 wrought and powder feedstock substrates. • Significant changes in crack resistance, solidification morphology observed with Ta substitution in the Hf-Nb-Mo-Ti family. • Predictive ductility and cracking criteria in tandem with single track experiments can assist refractory alloy design for AM. [ABSTRACT FROM AUTHOR]

Published

2024

31. Discovery of Ni activated sintering of MoNbTaW predicted by a computed grain boundary diagram.

Author

Shivakumar, Sashank, Song, Keqi, Wang, Chunyang, Lei, Tianjiao, Xin, Huolin L., Rupert, Timothy J., and Luo, Jian

Subjects

*CRYSTAL grain boundaries, *HEAT resistant alloys, *SINTERING, *PHASE diagrams, *POWDER metallurgy

Abstract

• Subsolidus Ni-activated sintering of MoNbTaW is discovered. • The first observation of activated sintering in a high-entropy alloy is made. • Grain boundary (GB) wetting is confirmed, implying subsolidus GB prewetting. • A GB diagram is computed to predict GB disordering and explain activated sintering. • Weak ni segregation in furnace-cooled specimens suggests GB drying during cooling. Activated sintering of refractory metals represents a classical phenomenon in powder metallurgy. This study discovers that Ni addition can enhance sintering of MoNbTaW both above and below the bulk solidus composition at 1800 °C, thereby demonstrating the first example of activated sintering of a high-entropy alloy. To probe the underlying mechanism, experiments reveal complete grain boundary (GB) wetting above the bulk solidus composition, which logically infers the stabilization of a liquid-like interfacial phase (GB complexion) in a prewetting region below the bulk solidus composition. Furthermore, bulk CALPHAD (calculation of phase diagram) methods have been extended to model GBs in Ni-doped MoNbTaW to compute a GB "phase" diagram to forecast high-temperature GB disordering in the prewetting region and rationalize the observed Ni-activated sintering of MoNbTaW. Only weak GB segregation of Ni is found in furnace-cooled specimens, which suggests GB "drying" during cooling, consistent with the observed nanoscale precipitates along GBs. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

32. An Investigation of the Miscibility Gap Controlling Phase Formation in Refractory Metal High Entropy Superalloys via the Ti-Nb-Zr Constituent System

Author

Tamsin E. Whitfield, George J. Wise, Ed J. Pickering, Howard J. Stone, and Nicholas G. Jones

Subjects

refractory alloys, high entropy alloys, complex concentrated alloys, spinodal decomposition, lattice misfit, microstructure, Mining engineering. Metallurgy, TN1-997

Abstract

Refractory metal high entropy superalloys (RSAs) have been heralded as potential new high temperature structural materials. They have nanoscale cuboidal bcc+B2 microstructures that are thought to form on quenching through a spinodal decomposition process driven by the Ta-Zr or Nb-Zr miscibility gaps, followed by ordering of one of the bcc phases. However, it is difficult to isolate the role of different elemental interactions within compositionally complex RSAs. Therefore, in this work the microstructures produced by the Nb-Zr miscibility gap within the compositionally simpler Ti-Nb-Zr constituent system were investigated. A systematic series of alloys with compositions of Ti5NbxZr95−x (x = 25–85 at.%) was studied following quenching from solution heat treatment and long duration thermal exposures at 1000, 900 and 700 °C for 1000 h. During exposures at 900 °C and above the alloys resided in a single bcc phase field. At 700 °C, alloys with 40–75 at.% Nb resided within a three phase bcc + bcc + hcp phase field and a large misfit, 4.7–5%, was present between the two bcc phases. Evidence of nanoscale cuboidal microstructures was not observed, even in slow cooled samples. Whilst it was not possible to conclusively determine whether a spinodal decomposition occurs within this ternary system, these insights suggest that Nb-Zr interactions may not play a significant role in the formation of the nanoscale cuboidal RSA microstructures during cooling.

Published

2021

33. Recent progresses on designing and manufacturing of bulk refractory alloys with high performances based on controlling interfaces.

Author

Zhang, T., Deng, H.W., Xie, Z.M., Liu, R., Yang, J.F., Liu, C.S., Wang, X.P., Fang, Q.F., and Xiong, Y.

Subjects

MOLYBDENUM alloys, ALLOYS, MOLYBDENUM, MECHANICAL properties of condensed matter, THERMAL conductivity, THERMAL resistance, TUNGSTEN, CREEP (Materials)

Abstract

Refractory alloys such as tungsten and molybdenum based alloys with high strength, thermal/electrical conductivity, low coefficient of thermal expansion and excellent creep resistances are highly desirable for applications in nuclear facilities, critical components in aerospace and defense components. However, the serious embrittlement limits the engineering usability of some refractory alloys. A lot of research results indicate that the performances of refractory alloys are closely related to the physical/chemical status, such as the interface dimension, interface type, interface composition of their grain boundaries (GBs), phase boundaries (PBs) and other interface features. This paper reviewed the recent progress of simulations and experiments on interface design strategies that achieve high performance refractory alloys. These strategies include GB interface purifying/strengthening, PB interface strengthening and PB/GB synergistic strengthening. Great details are provided on the design/fabrication strategy such as GB interface controlling, PB interface controlling and synergistic control of multi-scaled interfaces. The corresponding performances such as the mechanical property, thermal conductivity, thermal load resistance, thermal stability, irradiation resistance, and oxidation resistance are reviewed in the aspect to the effect of interfaces. In addition, the relationships between these interfaces and material properties are discussed. Finally, future developments and potential new research directions for refractory alloys are proposed. [ABSTRACT FROM AUTHOR]

Published

2020

34. On the design and feasibility of tantalum-base superalloys.

Author

Pickering, E.J., Christofidou, K.A., Stone, H.J., and Jones, N.G.

Subjects

*TANTALUM, *HEAT resistant alloys, *INTERNAL combustion engines, *GAS turbines, *ALLOYS, *HIGH temperatures

Abstract

In order to reduce the environmental impact of air travel, it is desirable that the efficiencies of gas turbine engines are increased. One way to achieve this goal is to increase the operating temperatures of the engine cores. Unfortunately for aero-engine manufacturers, the temperature capability limits of the Ni-base superalloys used currently have been reached. Hence, new alloys need to be developed that are capable of operating at significantly higher temperatures. In this article, the potential of tantalum-base superalloys is discussed and explored. A suite of alloys based on the Ta-Al-Co system was investigated. It was found that an array of fine carbide precipitates was formed in the Ta-rich matrix in a subset of the alloys, which is promising in terms of developing a strong and damage-tolerant microstructure, but that the elemental partitioning of Al out of the matrix accompanying precipitation is likely to degrade environmental resistance. Nevertheless, it is believed that the design principles described have the potential to facilitate the development of the next generation of high-temperature alloys based on systems of this type. • A suite of Ta-Al-Co alloys are designed and investigated. • Aim to produce BCC (A2) matrix + A2-superlattice precipitates. • Fine Ta3Al2CoC precipitates in Ta-rich BCC matrix found after ageing. • precipitates had a consistent orientation relationship with the matrix [ABSTRACT FROM AUTHOR]

Published

2019

35. High temperature strength of refractory complex concentrated alloys.

Author

Senkov, O.N., Gorsse, S., and Miracle, D.B.

Subjects

*HIGH temperatures, *ALLOYS, *PHASE diagrams

Abstract

Thermodynamic and mechanical properties of 15 single-phase and 11 multi-phase refractory complex concentrated alloys (RCCAs) are reported. Using the CALPHAD approach, phase diagrams for these alloys are calculated to identify the solidus (melting, T m) temperatures and volume fractions of secondary phases. Correlations were identified between the strength drops at 1000 °C and 1200 °C and the alloy compositions, room temperature properties, melting temperatures and volume fractions of secondary phases. The influence of alloy density on the temperature dependence of specific yield strength was also explored. The conducted analysis suggests that the loss of high-temperature strength of single-phase BCC RCCAs is related to the activation of diffusion-controlled deformation mechanisms, which occurs at T ≥ 0.6 T m , so that the alloys with higher T m retain their strength to higher temperatures. On the other hand, a rapid decrease in strength of multi-phase RCCAs with increasing temperature above 1000 °C is probably due to dissolution of secondary phases. Image 1 [ABSTRACT FROM AUTHOR]

Published

2019

36. CALPHAD-aided development of quaternary multi-principal element refractory alloys based on NbTiZr.

Author

Senkov, O.N., Zhang, C., Pilchak, A.L., Payton, E.J., Woodward, C., and Zhang, F.

Subjects

*TITANIUM alloys, *EQUILIBRIUM, *CHROMIUM-cobalt-nickel-molybdenum alloys, *PHASE transitions, *METAL solubility

Abstract

Abstract Equilibrium phase diagrams for ten Me X (NbTiZr) 100-X alloy systems, where Me is Al, Cr, Fe, Hf, Mo, Re, Si, Ta, V or W and X ranges from 0 to 25 at% were calculated using the PanNb2018a database recently developed by CompuTherm, LLC. By the type of phases and sequence of formation, these alloy systems can be divided into two groups. The first group of quaternary alloys, containing Al, Hf, Mo, Ta, or V has a single-phase BCC region below the solidus line over the entire X range and can be considered as potential candidates for the development of single-phase high entropy alloys. The second group consists of the quaternary alloy systems in which the fourth element (Cr, Fe, Re, Si or W) has limited solubility in BCC NbTiZr, which leads to the formation of an additional phase below the solidus and above the solubility limit. These quaternary alloy systems can be used for the development of precipitation or dispersoid strengthened complex concentrated alloys. To verify CALPHAD calculations three representative alloys, Cr 10 Nb 30 Ti 30 Zr 30 , Ta 10 Nb 30 Ti 30 Zr 30 and Re 10 Nb 30 Ti 30 Zr 30 , were prepared by arc melting. The alloy densities were 6.56, 7.81 and 7.85 g/cm3, respectively. The phase compositions of the produced alloys agreed satisfactorily with CALPHAD calculations. Mechanical properties were also studied and compared with those of NbTiZr. At room temperature (RT) all the alloys showed high hardness exceeding 350 Hv and high compression yield stress exceeding 1000 MPa. RT compression ductility of Re and Ta containing alloys was above 50%, but Cr-containing alloy showed low ductility of 5%. With an increase in temperature ≥800 °C, compression strength decreased more rapidly for the Cr-containing alloy, which at 1200 °C became softer than NbTiZr. The least temperature dependence of the strength was observed for the Ta-containing alloy, which became the strongest at 1200 °C. Highlights • Mo, Ta, V, Hf and Al have unlimited solubility range in BCC NbTiZr. • Cr, Fe, Re, Si and W have limited solubility in BCC NbTiZr resulting in secondary phases. • Alloying of NbTiZr with Ta and Re improve high-temperature mechanical properties. • Alloying of NbTiZr with Cr increases RT strength but softens the alloy at T ≥ 1000 °C. [ABSTRACT FROM AUTHOR]

Published

2019

37. Experimental investigation of phase equilibria in the Nb–Ni–Si refractory alloy system at 1073 K.

Author

dos Santos, Vinícius O., Tunes, Matheus A., Eleno, Luiz T.F., Schön, Cláudio G., and Richter, Klaus W.

Subjects

*NICKEL alloys, *PHASE equilibrium, *CHEMICAL systems, *HEAT treatment of metals, *X-ray spectroscopy, *COMPUTATIONAL physics

Abstract

Abstract Twelve different compositions of the ternary Nb–Ni–Si system were synthesized and heat-treated at 1073 K for up to 1000 h. The microstructure of the samples were analyzed using Scanning Electron Microscopy, Energy Dispersive X-ray Spectroscopy and X-ray Diffraction. The results from this work solve inconsistencies between the existing experimental information and the new computational predictions, in favor of the latter, due to the difficulty of reaching thermal equilibrium at this temperature. Graphical Abstract [ABSTRACT FROM AUTHOR]

Published

2019

38. Corrosion behavior of Hf0.5Nb0.5Ta0.5Ti1.5Zr refractory high-entropy in aqueous chloride solutions.

Author

Zhou, Qiongyu, Sheikh, Saad, Ou, Ping, Chen, Dongchu, Hu, Qiang, and Guo, Sheng

Subjects

*CHLORIDES, *CORROSION & anti-corrosives, *CURRENT density (Electromagnetism), *CORROSION resistance, *ALLOYS

Abstract

Abstract The Hf 0.5 Nb 0.5 Ta 0.5 Ti 1.5 Zr refractory high-entropy alloy with excellent corrosion resistance in the 3.5 wt% NaCl solution is identified in this work. This refractory high-entropy alloy exhibits much better general corrosion resistance than that of the 316L stainless steel, due to its corrosion current density being about one fifth of that in the latter. Meanwhile, the pitting potential of Hf 0.5 Nb 0.5 Ta 0.5 Ti 1.5 Zr reaches an unusually high value of +8.36 V, much higher than that of reported high-entropy alloys. The superior passivity of Hf 0.5 Nb 0.5 Ta 0.5 Ti 1.5 Zr is accredited to the formation of a single-phase solid solution containing high amount of homogenously distributed passivity-promoting elements, and also the existence of metallic Ta and OH− species in the passive film, which contribute to the high immunity to passive film breakdown. Highlights • Hf 0.5 Nb 0.5 Ta 0.5 Ti 1.5 Zr contains finely distributed passivity-promoting elements. • Hf 0.5 Nb 0.5 Ta 0.5 Ti 1.5 Zr exhibits better general corrosion resistance than 316L SS. • E pit of Hf 0.5 Nb 0.5 Ta 0.5 Ti 1.5 Zr reaches +8.36 V, beating all other reported RHEAs. [ABSTRACT FROM AUTHOR]

Published

2019

39. Fabrication and volume loading studies for Mo30W matrix surrogate cermets.

Author

Gaffin, Neal D., Palomares, Kelsa B., Milner, Justin L., and Zinkle, Steven J.

Subjects

*CERAMIC metals, *MOLYBDENUM alloys, *YTTRIA stabilized zirconium oxide, *LAVES phases (Metallurgy), *DENSITY matrices

Abstract

Ceramic-metallic composite (cermet) fuel forms are promising options for use in nuclear thermal propulsion (NTP) due to their high melting point, inherent hydrogen compatibility, retained strength at high temperatures, and high thermal conductivity. Spark plasma sintering was used to fabricate cermet materials, resulting in improved microstructural characteristics. An alloy of molybdenum with 30 wt% tungsten was used as the matrix material. Spherical yttria stabilized zirconia (YSZ) and both spherical and angular hafnium nitride (HfN) were used as surrogate fuel particles for the cermets. Utilizing a new lab-scale particle coating method, high density composites with excellent particle-matrix interfaces were fabricated. The effects of volume loading on the microstructure of the matrix were also examined, testing particle loadings up to 90 vol%. Initial stage sintering models were applied to understand the effects of the added particles on the sintering of the Mo30W matrix. Recommendations for fabrication of uranium bearing cermets using Mo30W are also included. • Mo30W cermets with nitride and oxide particles were sintered using SPS. • Effect of volume loading on matrix density was examined up to 90%. • Formation of Mo,W-Hf,N Laves phase characterized. • Effect of particles on initial stage sintering quantified. • Presented recommendations for sintering conditions for UO 2 and UN cermets. [ABSTRACT FROM AUTHOR]

Published

2023

40. High-temperature mechanical behaviors of a WTaRe refractory alloy manufactured by selective electron beam melting.

Author

Xiao, Bang, Jia, Wenpeng, Wang, Jian, and Zhou, Lian

Subjects

*ELECTRON beam furnaces, *ULTIMATE strength, *COMPRESSIVE strength, *CHROMIUM-cobalt-nickel-molybdenum alloys, *REFRACTORY materials

Abstract

Refractory alloys with their brilliant high-temperature tolerance earn a place for applications in extremely harsh environments. Recent development in additive manufacturing technologies speeds up these alloys' design and forming processes before entering the market. However, the desire for better microstructures and superior high-temperature mechanical behaviors has never been fed up. As was wished, in this study, an additively manufactured WTaRe alloy with compressive strength, ultimate compressive strength, and strain of 356 ± 15 MPa, 731 ± 15 MPa, and > 40% at 1600 °C is herein developed. Composition characterization after deformation of the as-deposited WTaRe alloy suggests the super high thermal stability of this alloy. Considering the excellent high-temperature mechanical behaviors, the printable WTaRe refractory alloy may serve as an alternative in a high-temperature environment. • The as-deposited WTaRe alloy has a superb thermal resistance up to 1600 °C. • Thecomposition of WTaRe alloy remains high-level homogeneity after deformed at 1200 °C, 1400 °C, and 1600 °C. • At 1600 °C, WTaRe alloy has the ultimate compressive strength and ductility of 731 ± 15 MPa and > 40%, respectively. [ABSTRACT FROM AUTHOR]

Published

2023

41. Konwersja materiałowo-technologiczna stopów niklu Część 2. Problemy technologiczne procesu odlewania.

Author

Pirowski, Zenon

Subjects

INDUCTION furnaces, MECHANICAL alloying, ALLOYS, HIGH temperatures, INCONEL

Abstract

Copyright of Transactions of the Foundry Research Institute / Prace Instytutu Odlewnictwa is the property of Lukasiewicz Research Network, Krakow Institute of Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2018

42. Compositional effect on microstructure and properties of NbTiZr-based complex concentrated alloys.

Author

Senkov, O.N., Rao, S., Chaput, K.J., and Woodward, C.

Subjects

*MICROSTRUCTURE, *ALLOYS, *MORPHOLOGY, *METALLIC composites, *MECHANICAL properties of metals

Abstract

Phase composition, microstructure and mechanical properties of six complex concentrated alloys, NbTiZr, NbTiZrV, NbTiZrVMo, NbTiZrVTa, NbTiZrVCr, and NbTiZrVAl 0.24 , are reported. The alloy density was in the range from 6.34 g/cm 3 to 8.43 g/cm 3 . After homogenization annealing at 1400 °C or 1200 °C, only the ternary NbTiZr alloy had a single-phase BCC crystal structure. NbTiZrV and NbTiZrVTa produced predominantly single-phase BCC structure with clusters of fine V-rich precipitates inside NbTiZrV grains and fine, Zr-rich grain boundary precipitates in NbTiZrVTa. The other three alloys contained BCC and Laves phases, and NbTiZrVMo also contained a second BCC phase. After compression deformation at 1000 °C, noticeable changes in the phase composition were found in NbTiZrV, NbTiZrVTa and NbTiZrVAl 0.24 , while the phase composition of other alloys retained unchanged. NbTiZr, NbTiZrV and NbTiZrVTa showed good ductility and noticeable work hardening rate at room temperature, while the ductility of other alloys rapidly decreased with increasing the amount of Laves phase. The RT yield stress varied from 975 MPa for NbTiZ to 1510 MPa for NbTiZrVMo. At 1000 °C, all the alloys showed excellent compression ductility; however only NbTiZrVCr and NbTiZrVMo were stronger than NbTiZr. The results indicate that increasing the composition complexity of refractory near-equiatomic alloys by increasing the number of the alloying elements does not necessary result in a simpler phase structure and/or better mechanical properties. The type of the alloying elements seems to be more important than their number. Additions of V, Al or Ta decrease while additions of Cr or Mo increase the 1000 °C strength of NbTiZr. [ABSTRACT FROM AUTHOR]

Published

2018

43. Boron capture stabilizing the diffusion barriers in a two-step Mo-Si-B coated refractory multi-principal element alloy.

Author

Su, Ranran, Zhang, Hongliang, Liu, Longfei, and Perepezko, John H.

Subjects

*REFRACTORY coating, *DIFFUSION barriers, *DIFFUSION coatings, *ALLOYS, *SOLID solutions, *TANTALUM, *THERMOCYCLING, *BORON

Abstract

A Mo-Si-B based coating has been applied on a refractory multi-principal element alloy (RMPEA) using a two-step coating strategy and has endured more than 750 h of thermal cycling oxidation exposure between room temperature to 1300 °C with a minimal weight change. The formation of the Mo 5 SiB 2 diffusion barrier in the coating prevents the inward diffusion of the coating components. Then, boron is captured by the RMPEA, resulting in the formation of a solid solution X 5 SiB 2 (X = W, Mo, Ta, Nb, V) layer and an RMPEA-B boride layer underneath it that acts as the second diffusion barrier. • A Mo-Si-B based coating was deverloped for a WMoTaNbV alloy by using a two-step coating strategy. • The diffusion pathway was modified by Mo and Si-B surface enrichment, resulting in a sequenced multilayered structure. • Boron is captured by the RMPEA substrate at the interface, enabling the formation of the second diffusion barrier. • The coating protects the WMoTaNbV from thermal cyclic oxidation for 750 × 1 h exposures at a 1300 °C. [ABSTRACT FROM AUTHOR]

Published

2023

44. High-toughness/resistivity ruthenium-based refractory alloy wires.

Author

Murakami, Rikito, Kamada, Kei, Umetsu, Kenichi, Yoshioka, Takashi, Oikawa, Katsunari, Kido, Junji, and Yoshikawa, Akira

Subjects

*TANTALUM, *ALLOYS, *ELECTRICAL resistivity, *TRANSMISSION electron microscopy, *WIRE, *TENSILE strength, *REFRACTORY materials

Abstract

High-resistivity Ru–Mo–W-alloy wires, exhibiting excellent strength and ductility, were fabricated using the micro-pulling-down melt-growth method under vacuum for application as resistance heating wires. Furthermore, their mechanical and electrical properties were investigated. The fabricated Ru 0.6 Mo 0.15 W 0.25 wires (⌀0.8 mm × 10.8 m long) showed a room-temperature tensile strength and nominal rupture strain of 1287 MPa and 21.2%, respectively. Transmission electron microscopy of Ru 0.6 Mo 0.15 W 0.25 revealed the presence of active 11 2 ¯ 2 < 11 2 ¯ 3 > pyramidal slip systems. Ru 0.6 Mo 0.15 W 0.25 demonstrated an electrical resistivity of ∼0.936 μΩ∙m at 1873 K, 1.77 and 1.24 times higher than those of W and Ta, respectively. The dependence of the hemispherical total emissivity on temperature was also measured. The temperature dependence of the electrical resistivity of Ru 0.6 Mo 0.15 W 0.25 was lower than those of Ta and W. Furthermore, the hemispherical total emissivities of Ru 0.6 Mo 0.15 W 0.25 and Ta were comparable at ∼1800 K. When tested at 1873 K for approximately 3000 h, the durability of a Ru 0.6 Mo 0.2 W 0.2 wire was equal or superior to that of a Ta wire. The current (power) consumption required to deposit LiF and tris (8-hydroxyquinolinato)aluminum(III) (Alq 3) at the same deposition rate using Ru 0.6 Mo 0.2 W 0.2 was 21% (11%) and 34% (12%) lower, respectively, than that when using conventional Ta heating wires. The results reveal that the Ru 0.6 Mo 0.15 W 0.25 heat-stabilization time was reduced by approximately 44%. Moreover, its deposition rate recovered more rapidly from errors such as a sudden boiling during heating. • The dewetting μ-PD method is used to grow single-crystal Ru–Mo–W alloy wires. • The alloy exhibits high tensile strength, ductility, and temperature durability. • The temperature dependence of its electrical properties is small. • It requires less current and power to deposit LiF and Alq 3 than a Ta wire. [ABSTRACT FROM AUTHOR]

Published

2023

45. The role of interstitial constituents in refractory complex concentrated alloys.

Author

Belcher, Calvin H., MacDonald, Benjamin E., Apelian, Diran, and Lavernia, Enrique J.

Subjects

*TRANSITION metal alloys, *ENERGY consumption in transportation, *HEAT resistant alloys, *ALLOYS, *DILUTE alloys, *TRANSITION metals

Abstract

To meet the growing demand for transportation and energy consumption around the world, more efficient turbine engines and power generators with higher operating temperatures are needed, which require alloys with retained strength levels at elevated temperatures. In the past decade, refractory complex concentrated alloys (RCCAs) have gained prominence through numerous reports of superior strengths at higher homologous temperatures compared to those of conventional refractory and super alloys. However, these RCCAs, comprised of transition metals from subgroups IV, V, and VI, tend to be brittle at room temperature, hindering their broad applicability. Recent findings reveal that interstitial constituents may significantly contribute to, and convolute observations of, the ductility and strength of RCCAs at room temperature. This review of the literature examines and discusses the field's current understanding of the role of interstitial constituents, specifically oxygen and nitrogen, in the microstructure and mechanical behavior of RCCAs. Moreover, we provide context derived from the binary interactions of interstitial constituents with refractory metals and their contribution to the development and processing of conventional refractory alloys as a framework to gain insight into interstitial constituent mechanisms in RCCAs. In some cases, the mechanisms of interstitial constituents in RCCAs are similar to those of unalloyed subgroup VI transition metals and their dilute alloys, segregating to and embrittling grain boundaries. In other cases, interstitial constituents can be accommodated in solid solution, strengthening the RCCA, similar to interstitial constituents soluble in unalloyed subgroup IV and V metals and their dilute alloys. With the understanding of interstitial constituent element interactions with RCCA constituents, more holistic approaches to the design of RCCAs are suggested to engineer the mechanisms of intended and unintended interstitial constituents through alloy design and processing. For the development of strong and ductile RCCAs, the interactions between interstitial constituents and RCCA constituents and their resulting mechanisms must be understood and controlled. [ABSTRACT FROM AUTHOR]

Published

2023

46. Modeling the influence of the composition of refractory elements on the heat resistance of nickel alloys by a deep learning artificial neural network

Author

Tarasov, D. A., Milder, O. B., Tiagunov, A. G., Tarasov, D. A., Milder, O. B., and Tiagunov, A. G.

Abstract

Nickel alloys are widely used in the manufacture of gas turbine parts. The alloys show resistance to mechanical and chemical degradation under prolonged loads and high temperatures. The properties of an alloy are determined by its composition and are subject to careful modeling. A set of basic refractory elements makes a special contribution to the parameters of the alloy. One of the main mechanical properties of the alloys is the high-temperature tensile strength. Determining the influence of certain elements on certain properties of an alloy is a complex scientific and engineering problem that affects the time and cost of developing new materials. Simulation is a great chance to cut costs. In this article, we predict high temperature strength based on the composition of refractory elements in alloys using a specially designed deep learning artificial neural network. We build the model based on prior knowledge of alloy composition, information on the role of alloying elements, type of crystallization, test temperature and time, and tensile strength. Successful simulation results show the applicability of this method in practice. © 2021 John Wiley & Sons, Ltd.

Published

2022

47. Development of Ductile Cr-Re Alloys for High Temperature Application in Aggressive Atmosphere : Overview

Author

Gimeno-Fabra, Lluís, Brodnikovsky, Nikolaj P., Krapivka, Nikolaj O., Corzo, María, Anglada i Gomila, Marc, Vlcek, Johannes, Senkov, Oleg N., editor, Miracle, Daniel B., editor, and Firstov, Sergey A., editor

Published

2004

48. Investigation of Phase Field Modeling for the Simulation of Solidification During Additive Manufacture of High-Temperature Alloys

Subjects

refractory alloys, IN718, phase field modeling, C103, solidification simulation, additive manufacturing

Abstract

In contrast with traditional manufacturing methods, additive manufacturing (AM) contributes material one layer at a time, until the component is complete. Despite the recognition powder bed fusion (PBF) has gained as a powerful tool for manufacturing, broad acceptance and large-scale production have been inhibited by limited predictability of the quality of the end product. This is highly dependent on the morphology that emerges during solidification. Phase field simulations are able to address some of the limitations of traditional systems for modeling solidification by incorporating the driving forces, determining the phase of the material from its lowest energy state, and providing a visual representation of the results. The nickel-based superalloy IN718 has been a prime candidate for a wide range of AM applications because of the desirable properties it possesses at high temperatures. As the alloy’s thermophysical properties and solidification behavior are well-documented, it is also a prime candidate for simulation development. The similar properties exhibited at high temperatures give reason to believe that the solidification behavior of refractory metals, for which thermophysical property data is not readily available, may be akin to that of other high-temperature alloys during additive manufacturing. Thus, it is proposed that a phase field model proven to be a valid approximation of the solidification morphology for IN718 could later be adapted for other refractory alloys, such as the niobium-based alloy C103. The objective of this research was to identify relationships that connect the process to the microstructural development and, ultimately, the behavior of high-temperature alloys during additive manufacturing through the development and use of a phase field model for the solidification of IN718. The study also sought to identify the processing parameters and thermophysical properties which have the greatest influence and ascertain the extent of their impact. Using the Multiphysics Object-Oriented Simulation Environment (MOOSE), an open-source, parallel finite element framework developed by Idaho National Laboratory, a phase field model was constructed and validated with physical experiments. A sensitivity analysis was then conducted with parameters and properties of interest. Based on the cellular morphology displayed at appropriate parameters, it was determined that this phase field model could serve as an approximation of solidification for IN718 during PBF. The model was also able to provide a concentration field that suggests solute partitioning of niobium within IN718, which is consistent with recently published literature. No single property was directly responsible for a transition between morphology types; however, the growth seemed to be determined by the combination of four factors: thermal diffusivity, interface mobility, gradient energy coefficient, and mode of anisotropy. Further testing would be required to ascertain whether or not this model can serve as an accurate depiction of solidification for C103 or other materials.

Published

2022

49. Structure of strengthening particles of niobium carbide in Fe-Cr-Ni cast refractory alloys.

Author

Kondrat'ev, S., Svyatisheva, E., Anastasiadi, G., and Petrov, S.

Abstract

Methods of optical and electron microscopies were used to study the structure of particles of niobium carbide in a cast refractory Fe-Cr-Ni-C alloy modified by Nb and Ti. Particles of niobium carbide in the structure of the cast alloy are predominantly multiphase polycrystalline clusters that are inhomogeneous in the chemical composition and crystal structure. The misorientation angle between individual crystals that compose the carbide particles is 30°-60°. The polycrystalline character of carbides is probably associated with significant thermal stresses that arise at the interphase boundaries in the structure of the alloy upon the primary cooling of the ingot. To explain the polymorphism of the cluster of niobium carbide, a further analysis of the structural and geometrical crystallography is required. [ABSTRACT FROM AUTHOR]

Published

2017

50. Crystallographic Mechanism of Local Lattice Turn Under Growth of Single Crystals of Refractory Nickel Alloys.

Author

Kablov, D., Kraposhin, V., and Talis, A.

Subjects

*CRYSTALLOGRAPHY, *LATTICE field theory, *SINGLE crystals, *NICKEL alloys, *ORIENTATION (Chemistry), *METALLIC surfaces

Abstract

Amechanism of local formation of crystals of random orientation in growth of single-crystal billets of refractory nickel alloys for blades of gas turbine engines is suggested. Aturn of the lattice is initiated at the place of contact between the initial melt and the surface of hard particles of NbC carbide and/or TiN nitride. [ABSTRACT FROM AUTHOR]

Published

2017