Microstructure and lifetime of Hf or Zr doped sputtered NiAlCr bond coat/7YSZ EB-PVD TBC systems

Muñoz-Saldaña, J.; Schulz, Uwe; Rodríguez, G.C. Mondragón; Cáceres-Díaz, L.A.; Lau, Hendrik

doi:10.1016/j.surfcoat.2017.12.017

Cited by 14 publications

(8 citation statements)

References 83 publications

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“…The FCT results of the Zr-doped samples of [52] in Fig. 6 apparently confirm the statement previously made for Y-doped samples in this study: the service life of TBCs becomes shorter, as the content of refractory elements in the substrates IN100 and CMSX-4 increases as to 1.3 → 5.5 at%.…”

Section: Fct Performance Of Zr or Hf Doped Tbc Systemssupporting

confidence: 89%

“…In this chapter, PVD related FCT experiments on TBC systems having a magnetron-sputtered bond coat doped with either Zr or Hf have been carried out by Saldaña, Schulz, Mondragón Rodríguez, Caceres-Diaz, and Lau. They are referred to in [52]. The magnetron-sputtered bond coats are Ni-36 Al-11Cr-0.8 X in at% with X being Zr or Hf.…”

Section: Fct Performance Of Zr or Hf Doped Tbc Systemsmentioning

confidence: 99%

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The mechanisms of controlling FCT life and failure mode of Ni-based EBPVD YSZ thermal barrier coatings via the effects of both substrate elements and reactive element doping

Fritscher

2020

SN Appl. Sci.

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Electron-beam physical vapor deposition (EBPVD) of NiCoCrAlY- and Hf-modified bond coats on (1) selected polycrystalline, directionally solidified, (2) single crystalline substrate alloys and (3) an uncoated NiCrAl bond-coat surrogate substrate, all of them covered with standard EBPVD YSZ topcoats were subjected to cyclic furnace testing (FCT) at 1100 °C. The lifetime and spallation failure upon FCT were evaluated. A typical mixed layer zone (MZ) of alumina and zirconia has formed during topcoat processing above the thermally growing oxide layer. The MZ was investigated by energy-dispersive X-ray spectroscopy after intermediate lifetimes and at the end of life. Chemical composition of the MZ and lifespan data were related to each other thus accounting for rate-determining reactions which could be assigned to either cation- or anion-controlled transport mechanisms. These provide a new approach to address FCT life and failure mode of even complex TBC systems containing reactive elements (e.g. Y and Hf). The cation-controlled processes are accelerated according to their concentration by tetravalent elements of the substrates, while the anion-controlled processes are unaffected by this and only adopt a cation-dominated mode when alloying elements of a low valence (e.g. Ti+) reach a supercritical concentration.

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Section: Fct Performance Of Zr or Hf Doped Tbc Systemssupporting

confidence: 89%

Section: Fct Performance Of Zr or Hf Doped Tbc Systemsmentioning

confidence: 99%

The mechanisms of controlling FCT life and failure mode of Ni-based EBPVD YSZ thermal barrier coatings via the effects of both substrate elements and reactive element doping

Fritscher

2020

SN Appl. Sci.

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“…Plotting the composition data measured by EDS in a Ni-Al-Cr ternary system following the site preference criteria of transition metals, reported by Jiang [29,36] allowed to predict the diffusion paths and thus the correspondent phase contents from the different processing conditions ( Figures 7 and 8). Based on the mentioned site preference criteria the following normalization model at 1100 °C was used for BC and superalloys: (Ni + Co + 0.28Mo + Re) (Al + Ti + 0.72Mo + Hf + W + Ta) (Cr) [36]. For instance, in the as-sprayed systems, Figure 7a shows the composition from the as-sprayed coatings in a 1100 ºC isothermal section of the Ni-Al-Cr ternary phase diagram, whereas the as-annealed system from coated IN100 superalloy is represented in Figure 7b.…”

Section: Phase Identification From a Normalization To A Ni-al-cr Systemmentioning

confidence: 99%

Microstructural analysis of Ta-containing NiCoCrAlY bond coats deposited by HVOF on different Ni-based superalloys

Mora-García

Ruiz-Luna

Mosbacher

et al. 2018

Surface and Coatings Technology

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The microstructural and chemical evolution after different processing steps of Ta-containing NiCoCrAlY bond coats (BC) sprayed by high velocity oxy-fuel on Ni-base superalloy (SA) substrates, top-coated with 7YSZ and furnace cycled at 1100 ºC focusing along the BC/SA interfaces is presented. Three superalloys were selected considering their Ta content relative to that within the BC: a) no Ta in the superalloy composition (IN100) and either b) similar or c) higher Ta content with respect to the BC (M247LC SX and CMSX-4, respectively). The processing conditions were as-sprayed, as-annealed, after EB-PVD deposition of a 7YSZ top coat, and after furnace cyclic tests (1100 ºC /120 h). The evolution of chemical composition after the different process steps are presented that include a normalization criteria to a Ni-Al-Cr system, elemental profiles as well as Weibull distribution plots of minor containing elements such as Ti, Ta, Mo, or W at the BC/SA interface. The effect of Ta was activated in some coated substrates by the presence of Ti and C in the superalloy consisting of inward Ta-diffusion, trapping of outward diffusing Ti and the subsequent formation of (Ta, Ti)-rich carbides in the BC avoiding possible segregation effects as titanium oxide in the oxide scale.

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“…The state of art topcoat material is 6-8 wt.% yttria-stabilized zirconia (YSZ) ceramic coating, which provides the advantages of low thermal conductivity, high thermal-expansion coefficient, and high fracture toughness [9][10][11]. YSZ topcoat can be deposited by mainly two methods: electron beam physical vapor deposition (EB-PVD) and air plasma spray method (APS) [12][13][14]. Interlayer bondcoat is between bond topcoat and substrate, which protects the superalloy substrate from being oxidized in severe environments and serves the critical role of providing adhesion between the substrate and the topcoat [15,16].…”

Section: Introductionmentioning

confidence: 99%

Effects of Al Sputtering Film on the Oxidation Behavior of NiCrAlY Bondcoat

Zhang

Yang³

et al. 2020

Coatings

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In this study, the oxidation behavior of Al coated NiCrAlY bondcoat is investigated. It is known that many methods are applied to improve the lifetime of bondcoat in thermal barrier coatings. Herein, the Al sputtering method is selected to increase the Al content, which does not change the structure of bondcoat. Thin Al film of ~2 µm was sputtered on the surface of bondcoat, which improved the oxidation resistance of NiCrAlY bondcoat. Experimental results showed that, after oxidation for 200 h at 1200 °C, the formation of a dense and continuous α-Al2O3/Cr2O3 multilayer was observed on the Al coated bondcoat surface. In contrast, a mixed oxides (NiO, Cr2O3 and spinel oxides) layer formed on the surface of the as-sprayed bondcoat samples. Results of the cyclic oxidation at 1050 °C within 204 h indicated that the Al sputtering method can improve the oxidation resistance of bondcoat. This study offers a potential way to prolong the lifetime of thermal barrier coatings and provides analysis of the oxidation mechanism.

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Microstructure and lifetime of Hf or Zr doped sputtered NiAlCr bond coat/7YSZ EB-PVD TBC systems

Cited by 14 publications

References 83 publications

The mechanisms of controlling FCT life and failure mode of Ni-based EBPVD YSZ thermal barrier coatings via the effects of both substrate elements and reactive element doping

The mechanisms of controlling FCT life and failure mode of Ni-based EBPVD YSZ thermal barrier coatings via the effects of both substrate elements and reactive element doping

Microstructural analysis of Ta-containing NiCoCrAlY bond coats deposited by HVOF on different Ni-based superalloys

Effects of Al Sputtering Film on the Oxidation Behavior of NiCrAlY Bondcoat

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