3.1 Weight gain kinetics
Figure 1 shows the weight gain kinetics of pure nickel and the Ni-Cr alloys exposed to three different atmospheres at 700°C. In general, weight gain kinetics in dry (Fig. 1a) and wet oxygen (Fig. 1b) were comparable, with the highest rate for Ni-5Cr and the lowest one for Ni-30Cr. In pure water vapor, however, the weight gain kinetics were much lower than those in both oxygen containing gases (Fig. 1c), and the highest weight gains were for Ni-20Cr and 30Cr in this case. For pure nickel, the weight gain kinetics were the lowest in water vapor only condition but much higher than those of Ni-30Cr in both wet and dry O2 conditions. It should be mentioned that the appearance of weight decreased with reaction time in dry O2 and H2O only condition could be related to possible scale spallation.
Assuming diffusion is the controlling step for all situations, the parabolic rate constants of weight gain kinetics, \({k}_{w}\), were calculated by the following equation.
$${\left(\frac{\text{∆W}}{\text{A}}\right)}^{\text{2}}\text{=2}{\text{k}}_{\text{w}}\text{t}$$
1
where \(\text{∆}\text{W}\) is the weight gain, \(\text{A}\) is the surface area of tested samples, and \(\text{t}\) is the reaction time. The calculated results were summarized in Table 1. The parabolic rate constants for Ni-10Cr in dry oxygen and Ni-30Cr in all three atmospheres were unavailable due to the irregular weight gain. The results showed clearly that the parabolic rate constants of Cr alloys (5-20Cr alloys) in wet oxygen were similar to those in dry oxygen. In pure water vapor, the parabolic rate constants were the lowest in all three environments.
Table 1
Parabolic oxidation rate constants, \({\varvec{k}}_{\varvec{w}}\)(10− 9·g2·cm− 4·s− 1), of Ni and Ni-Cr alloys reacted in different environments at 700°C.
Atmospheres | Ni | Ni-5Cr | Ni-10Cr | Ni-20Cr | Ni-30Cr |
Ar-20%O2 | 4.1 | 27.1 | - | 7.7 | - |
Ar-20%O2-20%H2O | 5.7 | 23.4 | 12.7 | 6.8 | - |
Ar-20%H2O | 0.2 | 0.8 | 0.4 | 0.5 | - |
- Data unavailable due to the irregular weight change |
3.2 Reaction product morphology
Figures 2a-c show metallographic cross-sections of pure Ni after exposure at 700°C in the three atmospheres for 100 h. In dry oxygen, a continuous and dense NiO layer with the thickness of approximate 10 µm was formed (Fig. 2a). In wet oxygen, the NiO scale was porous, with numerous pores distributed near the scale-alloy interface. The thickness was similar to that in dry oxygen (Fig. 2b), in line with the weight gain kinetics (Fig. 1b). In pure water vapor, the surface of pure nickel formed a very thin layer after 100 h reaction (Fig. 2c).
Further analysis using BSE-SEM is shown in Fig. 3, which provided more information about the morphology of the scale. The scales formed in both dry and wet oxygen were similar, with numerous pores mainly distributed in the inner part of the scale (Figs. 3a and 3b). In dry O2, the matrix and the scale were separated by a gap, while in wet oxygen, no such a gap was observed, and the oxide scale kept in a good contact with the alloy. In pure water vapor, however, there was a very thin dense and continuous NiO layer about 1 µm in thickness (Fig. 3c). These oxides were confirmed by XRD analysis (shown in Fig. 2d) to be NiO. After 300 h reaction, the morphologies of pure Ni in three atmospheres remained the same but the thickness increased. The measured thickness of oxide scale in different atmospheres is shown in Table 2.
Table 2
External NiO thicknesses of test alloys after reaction at 700°C in three atmospheres for 300 h (µm).
Atmospheres | Pure nickel | Ni-5Cr | Ni-10Cr | Ni-20Cr |
Ar-20O2 | 15 (± 2) | 13 (± 1) | 10 (± 1) | 9 (± 1)/ 5 (± 1) |
Ar-20O2-20H2O | 12 (± 1) | 12 (± 1) | 8 (± 1) | 7 (± 0.2) |
Ar-20H2O | 3 (± 0.3) | 3 (± 0.4) | 1.8 (± 0.2) | 2 (± 0.2) |
Figures 4a-c show the metallographic cross-sections of Ni-5Cr alloy after reaction for 100 h at 700°C in the three atmospheres. Compared with pure nickel in dry oxygen, the oxide morphology was changed significantly when adding 5 wt% Cr. The scale contained a three-layered structure: a top dense and continuous grey layer, an inner layer with some pores, and an internal oxidation zone (IOZ). There were gaps between the outer layer and the inner layer, and the inner layer and the IOZ. Surface X-ray diffraction (Fig. 4d) indicated that the oxide scale was composed of NiO and Cr2O3.
Further analysis by the BSE-SEM of the scale and EDS mapping (Fig. 5) indicated that the outer layer was mainly Ni-rich oxide and Cr was detected in the inner layer. According to the SEM image, the IOZ consisted of the needle-like precipitates which were scatteredly distributed in the alloy near the alloy-scale interface. These needle-like precipitates had been identified by TEM and EDS to be Cr2O3 in dry oxygen at 650°C [6]. Therefore, the top layer was NiO, followed by NiO and Cr2O3 mixture in the inner layer and Cr2O3 precipitates in the IOZ. After 300 h reaction, the cross-section morphology did not change much (not shown), and only the scale and IOZ became thicker.
By adding water in oxygen, the morphology did not change too much. The oxide scale (Fig. 4b) consisted of three layers which resembled that in dry oxygen. However, more pores were observed in the inner layer than those in dry oxygen. There were a dense NiO layer on the top, a porous NiO + Cr2O3 mixed inner layer, and the needle-like Cr2O3 internal precipitates inside the matrix. The XRD results (Fig. 4d) indicated that the components of the oxide scale were the same as those in dry oxygen. After 300 h reaction, the cross-section morphology had no change except the increased thickness (not shown).
When Ni-5Cr alloy was reacted in water vapor only condition, the morphology was changed significantly compared with those in dry and wet oxygen. The scale was much thinner than those in other two atmospheres. Figure 4c shows the metallographic cross-section image of the alloy after 100 h reaction where an IOZ can be observed. Further analysis by XRD indicated that the scale consisted of NiO and Cr2O3 (Fig. 4d). High magnification BSE-SEM image shown in Fig. 6a revealed a very thin external layer on the top of IOZ. The EDS point analysis results showed that this thin layer mainly consisted of nickel oxides. Therefore, the scale was composed of an external thin NiO layer and internal Cr2O3 precipitates. After 300 h reaction, the morphology was changed compared with that after 100 h reaction (shown in Fig. 6b). The NiO layer was much thicker (about 3 µm) than that after 100 h reaction (0.3 µm). Besides, some metallic Ni islands were visible beneath the NiO layer. The whisker shaped NiO formed on the top of NiO layer, and the IOZ contained both needle-like and fine precipitates. The thickness of IOZ increased significantly.
Figures 7a-c show the metallographic cross-sections of Ni-10Cr after 100 h reaction in the three atmospheres. Similar to Ni-5Cr, in dry and wet O2, the scale also had three layers which were the outer dense layer, the inner layer with few pores inside and IOZ. The XRD analysis is shown in Fig. 7d, which consisted of NiO and Cr2O3, that is, the outer layer was composed of NiO, the inner layer NiO and Cr2O3 mixture, and the IOZ with Cr2O3 precipitates. The scale thickness in dry and wet oxygen was more or less the same. The only difference was the inner layer formed in wet oxygen had the higher porosity than that in dry oxygen. After 300 h reaction, the morphology in both conditions remained the same (not shown). In pure water vapor, there was an IOZ near the surface in the matrix. Additionally, there were some light-color nodules covered by a dark layer formed on the top of the scale. The oxide scale contained Ni, NiO and Cr2O3 identified by XRD analysis (Fig. 7d). The thin top layer covering Ni nodules was NiO and the IOZ was with Cr2O3 precipitates. After 300 h reaction, the morphology was changed with a similar structure to that in Ni-5Cr after 300 h reaction. A thin NiO layer was observed with whisker-shaped NiO on the top of the scale, and the IOZ was separated by a metallic Ni layer.
Figures 8a-c show metallographic cross-sections of Ni-20Cr alloy after reaction in the three atmospheres for 100 h. In both dry and wet oxygen, the oxide scale structure was similar with that formed on the surface of Ni-10Cr in the same reaction condition, i.e., the outer light gray NiO layer, inner gray NiO and Cr2O3 mixture and internal Cr2O3 precipitates. In pure water vapor, the scale structure was also similar with that formed on the surface of Ni-10Cr in the same condition, i.e. the external light-color nodules wrapped by a thin dark oxide layer, and a rather thick internal oxidation zone. The oxide composition of the scale was similar to that of Ni-10Cr, which were NiO and Cr2O3 confirmed by the XRD (shown in Fig. 8d).
The metallographic cross-sections of Ni-30Cr alloy in the three conditions are shown in Figs. 9a-c. In dry and wet O2, the scale consisted of two different contrasts of thin dense layers without any internal oxidation zone observed. The scale was composed of NiO and Cr2O3 layers which were confirmed by XRD analysis (Fig. 9d).
A high magnification BSE-SEM image of the scale with EDS mapping is shown in Fig. 10. The mapping results indicated that the outer and inner layers were Ni-rich layer and Cr-rich layer, respectively. Combining these results, the external outer layer was NiO followed by Cr2O3 layer. After 300 h reaction, the morphology was similar to that in 100 h reaction.
The metallographic cross-section of the scale in water vapor only condition is shown in Fig. 9c, which consisted of the outer NiO nodules and the IOZ. There was a dense internal Cr2O3 band formed beneath the IOZ in contact with the matrix. The scale structure was the same as that of Ni-20Cr alloy in the same condition.
The measured external NiO thicknesses of different alloys after reaction in three atmospheres for 300 h are listed in Table 2. There was not much difference between dry and wet oxygen. The external NiO thickness in water vapor only condition was significantly lower than those in other two atmospheres.