Hot Corrosion Behavior of Hf-Doped NiAl Coating in the Mixed Salt of Na2SO4 + K2SO4 at 900 °C

doi:10.1007/s40195-023-01563-2

Abstract

Abstract:

The hot corrosion behavior of the NiAl coating and the 5Hf-NiAl coating induced by mixed salt at 900 °C was investigated. Comparing with the NiAl coating, the 5Hf-NiAl coating exhibited superior hot corrosion resistance because the addition of Hf promoted the formation of protective oxide scale and reduced the growth rate of oxide scale. Therefore, internal sulfides were not present in the 5Hf-NiAl coating after hot corrosion for 140 h. Cr exhibited different distribution in the two coatings since the addition of Hf changed the hot corrosion process of the coating. Hf and Ti in the 5Hf-NiAl coating trapped and captured sulfur, preventing the penetration of sulfur into the coating. The hot corrosion mechanism of the two coating and the effects of Hf on this process were discussed in this work.

Key words: Hot corrosion, Hafnium, Oxide scale, Titanium, Sulfide

W.L. Zhang, W. Li, L.B. Fu, X. Peng, J. Sun, S.M. Jiang, J. Gong, C. Sun. Hot Corrosion Behavior of Hf-Doped NiAl Coating in the Mixed Salt of Na₂SO₄ + K₂SO₄ at 900 °C[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(9): 1409-1420.

Figures/Tables 12

Fig. 1 Cross-sectional images of NiAl coating a and 5Hf-NiAl coating b, XRD patterns c

Fig. 2 Mass changes for the two coatings after hot corrosion in the mixed salt (75 wt% Na2SO4 + 25 wt% K2SO4) at 900 °C

Fig. 3 XRD patterns of the two coatings after hot corrosion in the mixed salt (75 wt% Na2SO4 + 25 wt% K2SO4) at 900 °C for 5 h and 140 h

Fig. 4 Cross-sectional images of the NiAl coating a and the 5Hf-NiAl coating b after hot corrosion for 5 h

Fig. 5 Higher magnification images and corresponding element mappings of the oxide scales of the NiAl coating a and the 5Hf-NiAl coating b, and internal oxides/sulfides of the NiAl coating c

Fig. 6 Cross-sectional images of the NiAl coating a and the 5Hf-NiAl coating b after hot corrosion for 140 h; higher magnification image and the corresponding element mappings of the oxide scale in the NiAl coating c

Fig. 7 Surface images of the NiAl coating a and the 5Hf-NiAl coating b after hot corrosion for 140 h

Fig. 8 EPMA mapping for the NiAl coating a and the 5Hf-NiAl coating b after hot corrosion at 900 °C for 140 h

Fig. 9 HAADF-STEM image and corresponding element mappings of the oxide scale/5Hf-NiAl coating interface after hot corrosion for 140 h, and SAED pattern of Ti sulfide

Fig. 10 Standard Gibbs free energy (\(\Delta G^\theta \)) of forming sulfides and oxides as a function of temperature (standardized to consuming 1 mol S2 or 1 mol O2)

Fig. 11 HAADF-STEM image and corresponding element mappings of the oxide of the 5Hf-NiAl coating after hot corrosion for 140 h, and SAED pattern of zone A and HRTEM image of zone B

Fig. 12 Schematic diagram showing the hot corrosion process of the two coatings in the mixed salt at 900 °C

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Hot Corrosion Behavior of Hf-Doped NiAl Coating in the Mixed Salt of Na₂SO₄ + K₂SO₄ at 900 °C

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