Effect of Pt-Al bond-coat on the tensile deformation and fracture behaviors of a second-generation SX Ni-based superalloy at elevated temperatures

An investigation was conducted into the influence of applying PtAl bond-coat on the tensile deformation and fracture behavior of second-generation single crystal superalloy substrate with the temperature ranging between room temperature RT and 1100 °C. In the meantime, the development of a two-layer...

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Bibliographic Details
Published in:Surface & coatings technology 2020-05, Vol.389, p.125640, Article 125640
Main Authors: Tao, X.P., Wang, X.G., Zhou, Y.Z., Tan, K.J., Liang, J.J., Yang, Y.H., Liu, J.L., Liu, J.D., Li, J.G., Sun, X.F.
Format: Article
Language:English
Subjects:
Aluminum
Coalescing
Coating effects
Deformation effects
Deterioration
Diffusion layers
Dimpling
Ductile fracture
Ductile-brittle transition
Elevated temperatures
Elongation
Fracture behaviors
Fracture mechanics
High temperature
Ni-based superalloy
Nickel base alloys
Platinum
Precipitates
Pt[sbnd]Al bond-coat
Room temperature
Single crystals
Stacking faults
Substrates
Superlattices
Temperature
Tensile deformation
Tensile properties
Tensile strength
Tensile tests
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Summary:An investigation was conducted into the influence of applying PtAl bond-coat on the tensile deformation and fracture behavior of second-generation single crystal superalloy substrate with the temperature ranging between room temperature RT and 1100 °C. In the meantime, the development of a two-layer PtAl bond-coat, consisting of an outer layer of single-phase β-(Ni,Pt)Al and an inter-diffusion zone of refractory metal precipitates, has also been discussed. As revealed by the results, the application of PtAl bond-coat contributed to a noticeable deterioration in both yield strength and ultimate tensile strength of the superalloy substrate at elevated temperatures. Nevertheless, the elongation of coated superalloy was shown to be 17.2% (at RT) and 10.4% (at 750 °C) lower and 9.6% (at 1100 °C) higher compared to uncoated samples. Following tensile test, the TEM analyses indicated that there were onsets of various slip systems, the traditional superlattice stacking faults were retarded at intermediate temperature and the dislocation debris could be increased to develop dislocation networks at higher temperature in the region of superalloy near the bond-coat. As the temperature was on the rise, the fracture mechanism of coated superalloy shifted from tearing ridges and dimples to quasi-cleavage and then to micro-void coalescence. While that of PtAl bond-coat was transformed from brittle to ductile rupture. Within the temperature range from RT up to 750 °C, a combination of long crack lengths and greater crack penetration depths into bond-coat caused more deterioration in the tensile properties of superalloy. When the temperature rose above 750 °C, the application of PtAl bond-coat improved the ductility of the substrate, as a result of the ductile failure in the bond-coat which hindered the development of through-thickness cracks. •PtAl coated superalloy tensile samples were tested at temperature between RT-1100 °C.•Dislocation density of superalloy nearby coating is higher than that of inner superalloy at all temperatures.•Presence of the coating reduces the tensile strength of the superalloy at all temperatures.•Above 750 °C, application of the coating does not have an adverse effect on the ductility of the superalloy.•Cracks density of failed PtAl coating decreases with the tensile temperature increase.
ISSN:0257-8972
1879-3347
DOI:10.1016/j.surfcoat.2020.125640