Observations on the oxidation and nitridation behaviour of oxide-dispersed chromium

Lawn, Richard E.; Wilson, F. G.; Desforges, C. D.

doi:10.1016/0022-5088(78)90076-0

Cited by 14 publications

(1 citation statement)

References 3 publications

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“…69 Dispersed spinel phases, such as MgO•Cr 2 O 3 and MgO•Al 2 O 3 , may take up nitrogen from a chromium matrix at nitrogen levels far in excess of those normally required to form chromium nitride precipitates in the pure (oxide free) metal. A similar effect has also been identified in chromium alloyed with yttria-dispersed chromium alloys (Cr-2Y 2 O 3 and Cr-5Y 2 O 3 ).…”

Section: High-temperature Ductilitymentioning

confidence: 99%

Chromium and chromium-based alloys: Problems and possibilities for high-temperature service

Harada

2004

JOM

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Beyond Ni-Based Superalloys OverviewThis article presents an overview of publications on mechanical properties of chromium and chromium-based alloys, with particular emphasis on ductility at low temperature and strength at high temperature. Analysis of rather scattered data suggests that a chromium or chromium-based alloy can be ductilized at ambient temperature and is quite capable of being strengthened to high levels at high temperature. A new composition design and process would open new opportunities for chromiumbased alloys as structural materials used at temperatures up to 1,300°C.

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Section: High-temperature Ductilitymentioning

confidence: 99%

Chromium and chromium-based alloys: Problems and possibilities for high-temperature service

Harada

2004

JOM

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High‐Temperature Oxidation and Corrosion of Intermetallics

Brady

Pint

Tortorelli

et al. 2013

Materials Science and Technology

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The sections in this article are Introduction Oxidation Fundamentals Protective Oxide Scale Formation Reactive Elements Overview Effects on Oxidation Production of Alloys with RE Additions Applicability and Limitations Pesting Ni  Al Based Intermetallics Overview Ni Al Transient Oxidation Steady‐State Oxidation Effect of Al Content Alloying Additions Other Corrosive Environments Ni 3 Al Transient Oxidation Steady‐State Oxidation Alloying Effects Fe  Al Based Intermetallics Overview Historical Perspective Thermodynamic and Kinetic Considerations in the Fe  Al  O System Fe 3 Al Fe Al Other Corrosive Environments Sulfur‐Containing Gases Chlorine‐Containing Gases Carbon‐Containing Gases Molten Salts and Condensed Deposits Ti  Al Based Intermetallics Overview Ti Al 2 Ti Al 3 τ Phase γ‐ Ti Al Thermodynamic Considerations The Nitrogen Effect Effects of Alloying Additions Engineering Considerations Other Corrosive Environments α 2 ‐ Ti 3 Al and Orthorhombic Ti 2 Al Nb α 2 Alloys Orthorhombic Alloys Nb  Al Based Intermetallics Overview Nb Al 3 Nb 2 Al Nb 3 Al Nb  Ti  Al Precious Metal, Exotic, and Miscellaneous Aluminides Pt  Al Intermetallics Ir  Al Intermetallics Ru  Al Intermetallics Co  Al Intermetallics V  Al Intermetallics Laves Phases and In‐Situ Composites Overview Single‐Phase Laves Alloys Nb  Nb Cr 2 In‐Situ Composites Cr XCr 2 Type In‐Situ Composites Ni Al ‐Based In‐Situ Composites γ‐ Ti Al + Ti ( Cr , Al ) 2 and Nb Al 3 + Nb ( Cr , Al ) 2 In‐Situ Composites Silicides Overview and General Considerations Mo Si 2 Overview High‐Temperature Oxidation Accelerated Oxidation and Pesting Effects of Alloying Additions Composites Other Corrosive Environments Mo 5 Si 3 Ti Si 2 and Ti 5 Si 3 Ti Si 2 Ti 5 Si 3 V 5 Si 3 Cr 3 Si Fe and Ni Silicides Other Silicides Beryllides Overview Complex Beryllides– MBe 13 , MBe 12 , and M 2 Be 17 MBe 2 MBe Phases Acknowledgements

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