Oxidation Behavior of Ru-Containing Ni-Base Single-Crystal Superalloys

Kawagishi, Kyoko; Sato, Atsushi; Sato, Akihiro; Kobayashi, Toshiharu; Harada, Hiroshi

doi:10.4028/www.scientific.net/msf.522-523.317

Cited by 23 publications

(35 citation statements)

References 7 publications

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“…TCPs break up the rafted microstructure [2] and deplete the matrix of solid-solution strengtheners [3]. Although the effect of Ru on ''reverse partitioning'' is the subject of debate, its effect on oxidation performance has been reported only at higher temperatures, typically C1,000°C [4][5][6][7][8][9]. At these temperatures, non-protective oxides form together with sub-surface oxidation.…”

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confidence: 96%

Intermediate Temperature Internal Oxidation in Fourth Generation Ru-bearing Single-Crystal Nickel-base Superalloys

et al. 2007

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Fourth-generation, Ru-bearing, Ni-base superalloys offer superior microstructural stability over previous generations, affording greater density-corrected creep strength, but in common with their predecessors, have only borderline ability to form and maintain a protective oxide layer. This is particularly so at intermediate temperatures of around 750°C at which temperature internal oxidation can occur. In this present study, the nature of this attack has been examined in experimental 3 and 5 mass % Ru alloys. Both these alloys exhibited dispersed regions of oxide-filled pits whose depth increased parabolically with isothermal exposure time at a similar rate. Pits appear to nucleate progressively straight from the initial competitive oxidation stage. In all cases, the pits were associated with a surface mound of nickel-and cobalt-rich oxides. The results of detailed metallographic examination of the internal oxidation products are provided.

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confidence: 96%

Intermediate Temperature Internal Oxidation in Fourth Generation Ru-bearing Single-Crystal Nickel-base Superalloys

et al. 2007

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“…Alloy E in Figure 2(e) contains a relatively high amount of Co, and Alloy D in Figure 2(d) contains the second highest amount of Co, compared with the other alloys in group B. Co is known as an element that degrades the oxidation resistance of Ni-base superalloys, because CoO grows faster than NiO [34]. Kawagishi also reported that a high amount of Re in substrate degrades the oxidation resistance of Nibase superalloys [2]. High amounts of Re and Ru are generally present in the group B alloy.…”

Section: Discussionmentioning

confidence: 99%

“…Recent Ni-base superalloys incorporate refractory elements, and these superalloys can consist of more than 10 elements. The addition of refractory elements to Ni-base superalloys is imperative for maintaining excellent creep properties and microstructural stability at elevated temperature; however, the oxidation behavior of these latest Ni-base superalloys is more complex than was found in previous alloys [1][2][3] due to these additional elements.…”

Section: Introductionmentioning

confidence: 91%

“…Nevertheless, some of these elements degrade the oxidation resistance of Nibase superalloys [2,23]. For example, adding Mo to third generation alloys deteriorates their oxidation resistance because of the formation of Mo oxide, which is more prone to volatilization.…”

Section: Discussionmentioning

confidence: 99%

“…Cr is generally considered as an important element to enhance oxidation resistance [32], whereas Re and Mo tends to degrade oxidation resistance of Ni-base superalloys. With regard to Ru, the effects are still controversial [1][2][3]21], however, some studies [1,21] reported that Ru-containing Ni-base superalloys show inferior oxidation resistance than the previous generation alloys, although Ru provides excellent microstructure stability that allows further addition of alloying elements for higher strength at an elevated temperature [33]. It would be rationalized that less Cr and high Mo, Re and Ru contents in later generation of Ni-base superalloys could effect for initial oxidation of Ni-base superalloys.…”

Section: Discussionmentioning

confidence: 99%

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Prediction of Initial Oxidation Behavior of Ni-base Single Crystal Superalloys: A New Oxidation Map and Regression Analysis

Suzuki¹,

Kawagishi²,

Yokokawa³

et al. 2012

Superalloys 2012 (Twelfth International Symposium)

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Predictions for oxidation behavior of Ni-base superalloys are becoming increasingly difficult because of the complex alloy composition. In this study, we focus on the initial oxidation behavior of Ni-base superalloys, and suggest a new oxidation map with using Al and Cr chemical potentials to distinguish the initial oxide type of Ni-base superalloys with seventy binary, ternary, and multicomponent Ni-base single crystal superalloys at 1100 °C. As a comparison of observed and calculated weight changes after one cycle at 1100 °C obtained by a regression analysis, seventy alloys demonstrated two distinct behaviors, which are divided heretofore into group A and group B. Microstructural observation revealed that an oxide layer in the group A alloys consists of Al 2 O 3 and/or spinel or complex oxide, whereas an oxide layer in the group B alloys consists of a thick NiO layer with an Al 2 O 3 internal subscale. Thermodynamic properties can reflect more effects of alloy elements in Ni-base superalloys, and Al and Cr activities, calculated by Thermo-Calc, were used as factors to distinguish the type of initial oxides. Group A and B alloys can clearly be divided according to Al and Cr activities. This was suggested as a new oxidation map to distinguish the initial oxide type of Ni-base superalloys, and possibly it can apply for any generation of Ni-base superalloys. In addition, empirical equations obtained from regression analysis were suggested to be used for predicting the weight change of alloys after one cycle at 1100 °C, and these could also be applied to all generations of Nibase superalloys. One equation exhibited excellent agreement between observed and calculated weight changes. The alloys that were applicable for this equation therefore had a compositional dependence.

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Prediction of Initial Oxidation Behavior of Ni‐Base Single Crystal Superalloys: A New Oxidation Map and Regression Analysis

et al. 2012

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Oxidation Behavior of Ru-Containing Ni-Base Single-Crystal Superalloys

Cited by 23 publications

References 7 publications

Intermediate Temperature Internal Oxidation in Fourth Generation Ru-bearing Single-Crystal Nickel-base Superalloys

Intermediate Temperature Internal Oxidation in Fourth Generation Ru-bearing Single-Crystal Nickel-base Superalloys

Prediction of Initial Oxidation Behavior of Ni-base Single Crystal Superalloys: A New Oxidation Map and Regression Analysis

Prediction of Initial Oxidation Behavior of Ni‐Base Single Crystal Superalloys: A New Oxidation Map and Regression Analysis

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