A defect-resistant Co–Ni superalloy for 3D printing

Murray, Sean P.; Pusch, Kira; Polonsky, Andrew; Torbet, Chris; Seward, Gareth; Zhou, Ning; Forsik, Stéphane A. J.; Nandwana, Peeyush; Kirka, Michael M.; Dehoff, Ryan R.; Slye, William; Pollock, Tresa M.

doi:10.1038/s41467-020-18775-0

Cited by 134 publications

(44 citation statements)

References 65 publications

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“…[122][123][124][125][126][127] The emergence of this new class of alloys was coincident with the thrust to develop new ICME tools, creating the opportunity for the design of alloys matched to PBF additive processes. [128,129] In this case study, the primary goals for alloy design were good high-temperature strength up to 1000°C (achieved by precipitation of a high volume fraction of the L1 2 phase), L1 2 solvus between 1100°C to 1250°C, high solidus and liquidus temperatures, high resistance to oxidation via alumina formation, and favorable printability. Nickel-base alloys strengthened with high volume fractions of L1 2 are well known for their tendency to crack during PBF printing.…”

Section: Limitationsmentioning

confidence: 99%

“…Additional details are given elsewhere. [129] Figure 9 shows a cross section normal to the [001] single crystal growth direction of the SB-CoNi-10 alloy and the associated analysis of distribution coefficients extracted from electron microprobe scans of the dendritic structure; details of this analysis are given elsewhere. [128,129] Significantly, the degree of segregation of the alloying elements as a function of fraction solid is less severe compared to nickel-base alloys, which also have wider freezing ranges compared to the CoNi alloys.…”

Section: Approachmentioning

confidence: 99%

“…[129] Figure 9 shows a cross section normal to the [001] single crystal growth direction of the SB-CoNi-10 alloy and the associated analysis of distribution coefficients extracted from electron microprobe scans of the dendritic structure; details of this analysis are given elsewhere. [128,129] Significantly, the degree of segregation of the alloying elements as a function of fraction solid is less severe compared to nickel-base alloys, which also have wider freezing ranges compared to the CoNi alloys. [141] The combined effect of lower solidification segregation, lower freezing ranges, and the 125°C solidus to solvus gap likely suppresses the tendency for liquid-mediated cracking during printing and subsequent cooling below the solidus temperature.…”

Section: Approachmentioning

confidence: 99%

“…Nevertheless, the design tools have been able to identify a promising composition from the ''printable'' point of view, with only one batch of powder being produced and standard ranges of printing parameters being employed in both L-PBF and E-PBF. [129] Given the combination of a high dimensional alloy design space and the complexity of the physics of PBF printing, suites of predictive tools will greatly enhance our ability to design ''printable'' alloys. [142] 4.…”

Section: Approachmentioning

confidence: 99%

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Design and Tailoring of Alloys for Additive Manufacturing

Pollock

Clarke

Babu

2020

Metall Mater Trans A

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Additive manufacturing (AM) promises a major transformation for manufacturing of metallic components for aerospace, medical, nuclear, and energy applications. This perspective paper addresses some of the opportunities for alloy and feedstock design to achieve site-specific and enhanced properties not attainable by conventional manufacturing processes. This paper provides a brief overview of the role of powders, as well as solidification and solid-state phase transformation phenomena typically encountered during fusion-based AM. Three case studies are discussed that leverage the above to arrive at microstructure control. The first case study focuses on approaches to modify the solidification characteristics by in-situ alloying. The second case study focuses on the need for concurrent design of alloys and processing conditions to arrive at the columnar to equiaxed transition during solidification. The third case study focuses on the design of a cobalt alloy for AM, with emphasis on tailoring liquid and solid state phase transformations. The need for comprehensive knowledge of processing conditions during AM, in-situ and ex-situ probing of microstructure development under AM conditions, and post-print processing, characterization, and qualification are articulated for the design of future alloys and component geometries built by AM.

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Section: Limitationsmentioning

confidence: 99%

Section: Approachmentioning

confidence: 99%

Section: Approachmentioning

confidence: 99%

Section: Approachmentioning

confidence: 99%

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Design and Tailoring of Alloys for Additive Manufacturing

Pollock

Clarke

Babu

2020

Metall Mater Trans A

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“…Compared to Direct Energy Deposition (DED), selective laser melting (SLM), which is laser-based powder bed fusion [6], is more suitable to fabricate small-scale components with complex geometries and high precision [7]. A wide variety of alloys have been utilized in SLM, ranging from superalloy [8,9], steel alloys [10,11], aluminum alloys [12,13], and titanium alloys [14,15]. Ti-6Al-4V (Ti-64) is the most extensively used titanium alloy due to its high specific strength, excellent corrosion resistance, and good mechanical performance [16].…”

Section: Introductionmentioning

confidence: 99%

Effects of Post Heat Treatments on Microstructures and Mechanical Properties of Selective Laser Melted Ti6Al4V Alloy

Liu

et al. 2021

Metals

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The unique thermal history of selective laser melting (SLM) can lead to high residual stress and a non-equilibrium state in as-fabricated titanium alloy components and hinders their extensive use. Post heat treatment, as a classical and effective way, could transform non-equilibrium α’ martensite and achieves desirable mechanical performance in SLMed Ti alloys. In this study, we aimed to establish the correlation between the microstructure and mechanical performances of SLMed Ti6Al4V (Ti-64) by using different heat treatment processes. The columnar prior β grain morphology and grain boundary α phase (GB-α) after different heat treatment processes were characterized, with their influences on the tensile property anisotropy fully investigated. Scanning electron microscope (SEM) observation of the fracture surface and its cross-sectional analysis found that the tensile properties, especially the ductility, were affected by the GB-α along the β grain boundary. Furthermore, the discontinuous ratio of GB-α was firstly proposed to quantitatively predict the anisotropic ductility in SLMed Ti-64. This study provides a step forward for achieving the mechanical property manipulation of SLMed Ti-64 parts.

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L1₂‐Strengthened Co‐Rich Alloys for High‐Temperature Structural Applications: A Critical Review

et al. 2021

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Tremendous efforts have been made to accelerate the design of advanced high‐temperature structural materials, leading to the development of high‐performance Ni‐based superalloys with both superior thermal stability and creep resistance. However, further gains in the temperature capabilities are difficult to achieve due to the narrow gap between the γ′‐solvus temperature and their melting temperatures within Ni‐based superalloys. Given the 50–150 °C advantages in the melting points of Co‐rich alloys than those of the Ni‐based superalloys, as well as the discovery of L12 precipitates in the ternary Co–Al–W alloys, the L12‐strengthened Co‐rich alloys are immediately recognized as the promising candidates to be developed as next‐generation high‐temperature structural materials. Follow‐up studies indicate that they also preserve a mild segregation tendency during solidification and superior particle coarsening resistance as compared with Ni‐based superalloys. Promising research directions in the field of Co‐rich high‐temperature alloys are also discussed herein, including thermodynamic‐guided alloy design, grain boundary characteristics, and their correlations with mechanical properties, as well as unique deformation mechanisms and particle shearing configurations.

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A defect-resistant Co–Ni superalloy for 3D printing

Cited by 134 publications

References 65 publications

Design and Tailoring of Alloys for Additive Manufacturing

Design and Tailoring of Alloys for Additive Manufacturing

Effects of Post Heat Treatments on Microstructures and Mechanical Properties of Selective Laser Melted Ti6Al4V Alloy

L1₂‐Strengthened Co‐Rich Alloys for High‐Temperature Structural Applications: A Critical Review

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A defect-resistant Co–Ni superalloy for 3D printing

Cited by 134 publications

References 65 publications

Design and Tailoring of Alloys for Additive Manufacturing

Design and Tailoring of Alloys for Additive Manufacturing

Effects of Post Heat Treatments on Microstructures and Mechanical Properties of Selective Laser Melted Ti6Al4V Alloy

L12‐Strengthened Co‐Rich Alloys for High‐Temperature Structural Applications: A Critical Review

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L1₂‐Strengthened Co‐Rich Alloys for High‐Temperature Structural Applications: A Critical Review