Michael L Santella scite author profile

Research Summary high-temperature AlloysHow would you… …describe the overall signifi cance of this paper?Alumina-forming austenitic stainless steels hold the potential to permit signifi cantly increased operating temperatures in aggressive high-temperature oxidizing environments encountered in energy conversion and chemical process industry applications.…describe this work to a materials science and engineering professional with no experience in your technical specialty?We have discovered that creepresistant, austenitic stainless steels capable of protective aluminumoxide scale formation, rather than conventionally used chromium-oxide scales, are feasible. This results in signifi cantly improved oxidation resistance and higher-temperature capability in many industrially relevant environments. …describe this work to a layperson?This paper describes the development of a new type of stainless steel with improved corrosion resistance for hightemperature use in power generation. The corrosion protection is derived from aluminum additions to the alloy instead of typically used chromium additions.Author's Note: Part of this research summary is based on a recent review paper (see Reference 1) and fi ndings fi rst reported in References 2-7.

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Overview of Strategies for High-Temperature Creep and Oxidation Resistance of Alumina-Forming Austenitic Stainless Steels

Yamamoto

Brady

Santella

et al. 2010

Metall Mater Trans A

156

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A family of creep-resistant, alumina-forming austenitic (AFA) stainless steel alloys is under development for structural use in fossil energy conversion and combustion system applications. The AFA alloys developed to date exhibit comparable creep-rupture lives to state-of-the-art advanced austenitic alloys, and superior oxidation resistance in the~923 K to 1173 K (650°C to 900°C) temperature range due to the formation of a protective Al 2 O 3 scale rather than the Cr 2 O 3 scales that form on conventional stainless steel alloys. This article overviews the alloy design approaches used to obtain high-temperature creep strength in AFA alloys via considerations of phase equilibrium from thermodynamic calculations as well as microstructure characterization. Strengthening precipitates under evaluation include MC-type carbides or intermetallic phases such as NiAl-B2, Fe 2 (Mo,Nb)-Laves, Ni 3 Al-L1 2 , etc. in the austenitic single-phase matrix. Creep, tensile, and oxidation properties of the AFA alloys are discussed relative to compositional and microstructural factors.

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Advances in processing of Ni3Al-based intermetallics and applications

Deevi²,

et al. 2000

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Composition, Microstructure, and Water Vapor Effects on Internal/External Oxidation of Alumina-Forming Austenitic Stainless Steels

et al. 2009

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Effects of friction stir processing on mechanical properties of the cast aluminum alloys A319 and A356

et al. 2005

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