Progressive damage evolution leading to spallation was investigated in Electron Beam—Plasma Vapor Deposition (EB-PVD) partially stabilized zirconia thermal barrier coating (TBC) applied to Nickel-based single crystal superalloy, Rene N5 with PtAl bondcoat. Thermal cycles were between 200-1177C. Progressive damage evolution was monitored using microscopy on samples subjected to a series of thermal cycles. Fick’s law can describe the thermally grown oxide (TGO) thickness for early cycles. However, at higher number of thermal cycles, damage in the form of microcracks and their link-up results in the development of a larger delamination crack through the TGO layer and monitoring oxide thickness becomes difficult. Thus, both oxidation kinetics and damage appears to play significant roles as they relate to spallation. As the early microcracks coalesce to form a major delamination crack, the susceptibility for TBC buckling is increased. The damage thickness continues to increase with number of thermal cycles indicating a progressive buckling condition. Estimation shows that a delamination crack length of about sixteen times the TBC thickness is needed for the current material system to cause buckling. Progressive microcrack linking to form a large delamination crack followed by progressive buckling of the TBC layer appear to promote spallation. Physical evidence of microcrack link-up and progressive buckling was found in specimens prior to complete spallation.

Issue Section:
Technical Papers
Topics:
Damage, Thermal barrier coatings, Buckling, Cycles, Delamination, Fracture (Materials), Microcracks, Spallation (Nuclear physics), Cathode ray oscilloscopes, Crystals, Electron beams, Microscopy, Nickel, Oxidation, Plasmas (Ionized gases), Superalloys, Vapor deposition
1.
Aifantis
E. C.
,
1980
, “
On the Problem of Diffusion in Solids
,”
Acta Mechanica
, Vol.
37
, pp.
265
296
.
2.
Brindley, W. J., 1995, “Properties of Plasma Sprayed Bond Coats,” Proceedings of TBC Workshop, NASA-LeRC, pp. 189–202.
3.
Chang
G. C.
,
Phucharoen
W.
, and
Miller
R. A.
,
1987
, “
Finite Element Thermal Stress Solutions for Thermal Barrier Coatings
,”
Surface and Coatings Technology
, Vol.
32
, pp.
307
325
.
4.
Evans
A. G.
,
Crumley
G. B.
, and
Demaray
R. E.
,
1983
, “
On the Mechanical Behavior of Brittle Coatings and Layers
,”
Oxidation of Metals
, Vol.
20
, Nos.
5/6
, pp.
193
214
.
5.
Evans
A. G.
, and
Hutchinson
J. W.
,
1984
, “
On the Mechanics of Delamination and Spalling in Compressed Films
,”
Int. J. Solids Structures
, Vol.
20
, No.
5
, pp.
455
466
.
6.
Evans
H. E.
,
1989
, “
Cracking and Spalling of Protective Oxide Layers
,”
J. of Materials Science and Engineering
, Vol.
A120
, pp.
139
146
.
7.
Meier
S. M.
,
Nissley
D. M.
,
Sheffler
K. D.
, and
Cruse
T. A.
,
1992
, “
Thermal Barrier Coating Life Prediction Model Development
,”
ASME Journal of Engineering for Gas Turbines and Power
, Vol.
114
, pp.
258
263
.
8.
Miller
R. A.
, and
Lowell
C. E.
,
1982
, “
Failure Mechanisms of Thermal Barrier Coatings Exposed to Elevated Temperature
,”
Thin Solid Films
, Vol.
95
, pp.
265
273
.
9.
Neu
R. W.
, and
Sehitoglu
H.
,
1989
, “
Thermomechanical Fatigue, Oxidation, and Creep: Part I. Damage Mechanisms
,”
Met. Trans.
, Vol.
A 20A
, pp.
1755
1767
.
10.
Neu
R. W.
, and
Sehitoglu
H.
,
1989
, “
Thermomechanical Fatigue, Oxidation, and Creep: Part II. Life Prediction
,”
Met. Trans.
, Vol.
A 20A
, pp.
1769
1783
.
11.
Nusier, S. Q., and Newaz, G. M., 1996, Unpublished Results, Wayne State University, Detroit.
12.
Siegler
D. R.
,
1993
, “
Adherence Behavior of Oxide Grown in Air and Synthetic Exhaust Gas on Fe-Cr-Al Alloys Containing Strong Sulfide Forming Elements Ca, Mg, Y, Ce, La Ti and Zr
,”
Oxidation of Metals
, Vol.
40
, pp.
555
583
.
13.
Strangman
T. E.
,
1992
, “
Thermal Strain-Tolerant Abradable Thermal Barrier Coatings
,”
ASME Journal of Engineering Gas Turbines and Power
, Vol.
114
, pp.
264
267
.
14.
Suo
Z.
,
1995
, “
Wrinkling of the Oxide Scale on an Aluminum-Containing Alloy at High Temperatures
,”
J. of Mechanics of Physics and Solids
, Vol.
43
, No.
6
, pp.
829
846
.
15.
Thompson, J. M. T., and Hunt, G. W., 1973, A General Theory of Elastic Stability, Wiley, New York.
16.
Tolpygo
V. K.
, and
Grabke
H. J.
,
1994
, “
Microstructural Characterization and Adherence of the α-Al2O3 Oxide Scale on the Fe-Cr-Al and Fe-Cr-Al-Y Alloys
,”
J. of Oxidation of Metals
, Vol.
41
, pp.
343
364
.
17.
Wittig, L. A., 1993, “A Micromechanical Model of Oxidation Effects in SiC/Ti Metal Matrix Composites,” Master’s thesis, Texas A&M University, College Station, Texas.
18.
Wittig
L. A.
, and
Allen
D. H.
,
1994
, “
Modeling the Effects of Oxidation on Damage in SiC/Ti-15-3 Metal Matrix Composites
,”
ASME JOURNAL OF ENGINEERING MATERIALS AND TECHNOLOGY
, Vol.
116
, pp.
421
427
.
19.
Wright, K. P., 1996, Private Communictaion, GE, Evendale, Ohio.
This content is only available via PDF.
Copyright © 1998
 by The American Society of Mechanical Engineers
You do not currently have access to this content.