Sammy Tin scite author profile

The chemical, physical, and mechanical characteristics of nickel-based superalloys are reviewed with emphasis on the use of this class of materials within turbine engines. The role of major and minor alloying additions in multicomponent commercial cast and wrought superalloys is discussed. Microstructural stability and phases observed during processing and in subsequent elevated-temperature service are summarized. Processing paths and recent advances in processing are addressed. Mechanical properties and deformation mechanisms are reviewed, including tensile properties, creep, fatigue, and cyclic crack growth.

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Directional solidification of large superalloy castings with radiation and liquid-metal cooling: A comparative assessment

Elliott

Pollock

Tin

et al. 2004

Metall Mater Trans A

178

111

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A columnar-grain variant of single-crystal RENÉ N4 has been directionally solidified (DS) over a range of conditions in order to assess the possible benefits of the use of liquid metal-enhanced cooling for large cross-sectional castings. Castings were solidified at a rate of 2.5 mm/min using conventional radiation cooling and at rates between 2.5 and 8.5 mm/min using liquid-metal cooling (LMC) with tin as a cooling medium. Thermocouples inserted in the casting directly measured thermal gradients during solidification. The LMC process exhibited higher gradients at all withdrawal rates. The higher thermal gradients resulted in a refined structure measurable by the finer dendrite-arm spacing. Additionally, the conventionally cast material exhibited several freckle-type defects, while none were observed in the liquid-metal-cooled castings.

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Ultrahigh Strength of Dislocation‐Free Ni₃Al Nanocubes

Maaß

Meza

Gan

et al. 2012

Small

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Individual Ni(3) Al nanocubes under pressure are investigated by comparing the compressive strength of both dislocation-free and irradiated Ni(3) Al nanocubes. The results are dicussed in light of the size-dependent and size-independent strength of face-centered cubic (fcc) nanocrystals in the framework of dislocation nucleation at free surfaces. This study sheds more light on the understanding of fundamental deformation mechanisms and size-affected strength in dislocation-free metallic nanocrystals.

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Identification of the partitioning characteristics of ruthenium in single crystal superalloys using atom probe tomography

et al. 2004

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Sammy Tin

Nickel-Based Superalloys for Advanced Turbine Engines: Chemistry, Microstructure and Properties

Directional solidification of large superalloy castings with radiation and liquid-metal cooling: A comparative assessment

Ultrahigh Strength of Dislocation‐Free Ni₃Al Nanocubes

Identification of the partitioning characteristics of ruthenium in single crystal superalloys using atom probe tomography

Contact Info

Product

Resources

About

Sammy Tin

Nickel-Based Superalloys for Advanced Turbine Engines: Chemistry, Microstructure and Properties

Directional solidification of large superalloy castings with radiation and liquid-metal cooling: A comparative assessment

Ultrahigh Strength of Dislocation‐Free Ni3Al Nanocubes

Identification of the partitioning characteristics of ruthenium in single crystal superalloys using atom probe tomography

Contact Info

Product

Resources

About

Ultrahigh Strength of Dislocation‐Free Ni₃Al Nanocubes