The development of silicon‐containing oxides during the oxidation of iron‐chromium‐base alloys

Stott, F.H.; González, Gabriel J.; Wei, Feng; Wood, G. C.

doi:10.1002/maco.19870380910

Cited by 54 publications

(34 citation statements)

References 25 publications

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“…the AES results discussed above) is fully amorphous (in accordance with results reported in Ref. 22). …”

Section: Resultssupporting

confidence: 79%

“…Although small additions of Si to Cr 2 O 3 -scale-forming steel are known to improve its high-temperature corrosion resistance (in particular, it enhances the reformation of a protective Cr 2 O 3 scale on the barealloy surface after oxide spallation [3,10,[12][13][14][15]), a fundamental understanding of this effect lacks [15][16][17][18]. The Si content corresponding with the maximum oxidation resistance (i.e., the longest breakaway oxidation time at constant temperature) appears to depend strongly on the steel microstructure [3,10,13,[19][20][21][22].…”

Section: Introductionmentioning

confidence: 99%

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Oxidation Behavior of Fe–25Cr–20Ni–2.8Si During Isothermal Oxidation at 1,286 K; Life-time Prediction

Bauer

Baccalaro

Jeurgens³

et al. 2008

Oxid Met

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The oxidation behavior of an austenitic steel, type 1.4841, with a Cr content of 25 wt% and a high-Si content of 2.8 wt% was studied during isothermal oxidation at 1,286 K in air. A thick, crystalline Cr 2 O 3 layer, on top of a much thinner, amorphous SiO 2 layer, developed on the alloy substrate. After formation of a closed Cr 2 O 3 scale, parabolic growth kinetics prevailed as long as the associated constant, steady-state Cr concentration in the alloy at the substrate/oxide interface of about 13 ± 1 wt% was maintained. Upon prolonged oxidation, successive cracking and spallation of the thickening oxide scale eventually led to breakaway oxidation, because the ''bulk-''Cr concentration in the interior of the alloy dropped below the critical value required to 'heal' the protective oxide layer after oxide spallation. Application of a lifetime prediction model of the alloy substrate under isothermal oxidation conditions allowed determination of the breakaway-oxidation time as a function of alloy-sheet thickness, by employing the Cr volume-diffusion coefficient in the alloy and the parabolic growth-rate constant, both determined in the present study by fitting calculated to experimental Cr-depletion profiles for various oxidation times.

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“…the AES results discussed above) is fully amorphous (in accordance with results reported in Ref. 22). …”

Section: Resultssupporting

confidence: 79%

Section: Introductionmentioning

confidence: 99%

Oxidation Behavior of Fe–25Cr–20Ni–2.8Si During Isothermal Oxidation at 1,286 K; Life-time Prediction

Bauer

Baccalaro

Jeurgens³

et al. 2008

Oxid Met

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“…An amorphous silica layer, which was believed to act as a diffusion barrier to reduce iloxidation rates, has been detected [20][21][22] at oxide/alloy interfaces in alloys con_ning Si, and the presence of such a silica layer also increased scale spallation [21]. In the present study, the silica layer was never found to be continuous.…”

Section: Oxide Morphology and Compositi0ncontrasting

confidence: 38%

Oxidation Behavior of Co-15wt% Cr Alloy Containing Dispersed Oxides Formed by Internal Oxidation

1992

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Internal oxidation pretreatments of Co-15wt%Cr and Co-15wt%Cr-1 wt% Ti were carried out using a Rhines pack in quartz, in mullite, and in alumina. A dispersion of titanium oxide particles formed in the Ti-containing alloy as a result of the internal oxidation. However, silicon also diffused into all treated specimens when the pretreatments were carried out in quartz or in mullite. The effect of various pretreatments on the subsequent oxidation of these alloys was studied at 1,000°C and compared with that of a Co-15wt%Cr-1wt%Si alloy. The main purpose of this study was to determine the relative effectiveness of the dispersed oxide particles and the contaminated silicon on the selective oxidation of chromium. It was found that the oxidation behaviors of both treated alloys were strongly affected by the degree of silicon contamination. Selective oxidation of chromium to form a nearly continuous protective Cr2O3 scale was achieved with greater than 0.4 wt% silicon. The presence of dispersed particles reduced initial oxidation rate but was ineffective in promoting Cr2O3 scale formation.

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“…The former was inferred to be SiO 2 . Addition of Si is known to improve the oxidation resistance of chromia-forming alloys [10][11][12]; however, it is also known to decrease scale spallation resistance [12][13][14]. Apparently, the nominally 2.75 wt% Si addition in the HR-160 alloy forms a continuous SiO 2 layer at the chromia/alloy interface and this in turn may have considerably decreased scale adhesion particularly at 982 o C. It is seen from Table III that HR-160 alloy underwent considerable metal loss (~ 43 µm) at 982 o C even though it contains sufficient amount of Cr to establish a protective oxide scale.…”

Section: Resultsmentioning

confidence: 99%

Long-Term Cyclic-Oxidation Behavior of Selected High Temperature Alloys

Deodeshmukh¹,

Srivastava²

2008

Superalloys 2008 (Eleventh International Symposium)

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Long-term cyclic oxidation resistance is often needed for high temperature alloys used in gas turbine engines for extending their operating lives. This study evaluates the cyclic-oxidation behavior of commercially available Ni-(HAYNES ® 230 ® , 214 ® , HASTELLOY ® X, and HR-160 ® alloys) and Fe-based alloys (HR-120 ® and 556 ® alloys) in flowing air at 982 o C, 1093 o C, and 1149 o C for a total exposure of one year. Test samples were thermally cycled every 30 days at temperature followed by air cooling to room temperature. Alloy performances were assessed by analyzing the weight-change behavior and extent of attack, as measured by metal loss and average internal penetration. The results clearly demonstrated the effects of alloy composition and temperature on long-term cyclic oxidation resistance. The 214 alloy exhibited superior oxidation performance owing to its ability to form and maintain protective alumina scale. Amongst the chromia-formers, 230 alloy performed the best at all temperatures; while Fe-based alloys exhibited rather poor oxidation resistance due to poor scale adhesion. By contrast, the HR-160 alloy showed the lowest weight-loss at 1149 o C of the chromia-forming alloys; however, this alloy underwent extensive internal attack. This study also compared cyclic oxidation resistance of 230, HR-120, and HR-160 alloys in flowing and still air. It was found that alloy composition has a profound effect on the extent of oxidation in flowing air compared to that in still air. For instance, the Fe-based HR-120 alloy exhibited improved performance in flowing air while Ni-based alloys (230 and HR-160 alloys) performed better in still air. The factors that may have influenced the oxidation behavior of alloys in flowing and still air will be discussed.

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The development of silicon‐containing oxides during the oxidation of iron‐chromium‐base alloys

Cited by 54 publications

References 25 publications

Oxidation Behavior of Fe–25Cr–20Ni–2.8Si During Isothermal Oxidation at 1,286 K; Life-time Prediction

Oxidation Behavior of Fe–25Cr–20Ni–2.8Si During Isothermal Oxidation at 1,286 K; Life-time Prediction

Oxidation Behavior of Co-15wt% Cr Alloy Containing Dispersed Oxides Formed by Internal Oxidation

Long-Term Cyclic-Oxidation Behavior of Selected High Temperature Alloys

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