Damage progression in thermal barrier coating systems during thermal cycling: A nano-mechanical assessment

Damage progression in thermal barrier coating systems during thermal cycling: A nano-mechanical assessment

This paper studies how the nano-mechanical properties of thermal barrier coatings (TBCs) vary during thermal cycling, as a way to shed new light on their failure mechanisms. In particular, high-throughput nanoindentation revealed the evolution of hardness and elastic modulus distributions of plasma-...

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Main Authors: Giovanni Bolelli, Maria Grazia Righi, Muhammad Zeeshan Mughal, Riccardo Moscatelli, Omar Ligabue, Nelso Antolotti, Marco Sebastiani, Luca Lusvarghi, Edoardo Bemporad
Format: Article
Language:English
Published: Elsevier 2019-03-01
Series:Materials & Design
Online Access:http://www.sciencedirect.com/science/article/pii/S0264127519300528
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spelling doaj-20f2bb5984f3489f80ce51304a5da1e22020-11-25T02:11:19ZengElsevierMaterials & Design0264-12752019-03-01166Damage progression in thermal barrier coating systems during thermal cycling: A nano-mechanical assessmentGiovanni Bolelli0Maria Grazia Righi1Muhammad Zeeshan Mughal2Riccardo Moscatelli3Omar Ligabue4Nelso Antolotti5Marco Sebastiani6Luca Lusvarghi7Edoardo Bemporad8Department of Engineering “Enzo Ferrari”, University of Modena and Reggio Emilia, Via Pietro Vivarelli 10/1, I-41125 Modena, MO, Italy; Corresponding author.Department of Engineering “Enzo Ferrari”, University of Modena and Reggio Emilia, Via Pietro Vivarelli 10/1, I-41125 Modena, MO, ItalyRoma Tre University, Engineering Department, Via della Vasca Navale 79, 00146 Rome, ItalyRoma Tre University, Engineering Department, Via della Vasca Navale 79, 00146 Rome, ItalyTurbocoating S.p.A., via Mistrali 7, I-43043 Rubbiano di Solignano, PR, ItalyTurbocoating S.p.A., via Mistrali 7, I-43043 Rubbiano di Solignano, PR, ItalyRoma Tre University, Engineering Department, Via della Vasca Navale 79, 00146 Rome, ItalyDepartment of Engineering “Enzo Ferrari”, University of Modena and Reggio Emilia, Via Pietro Vivarelli 10/1, I-41125 Modena, MO, ItalyRoma Tre University, Engineering Department, Via della Vasca Navale 79, 00146 Rome, ItalyThis paper studies how the nano-mechanical properties of thermal barrier coatings (TBCs) vary during thermal cycling, as a way to shed new light on their failure mechanisms. In particular, high-throughput nanoindentation revealed the evolution of hardness and elastic modulus distributions of plasma-sprayed yttria-stabilized zirconia (YSZ) top layers. The evolution of fracture toughness of the YSZ layers and the thermally grown oxide (TGO) formed onto the vacuum plasma-sprayed NiCoCrAlY bond coat were investigated by nanoindentation micro-pillar splitting.The TGO fracture toughness increases up to ≈2.5–3.5 MPa√m at the early stages of thermal cycling, followed by a rapid decrease to ≈2.0 MPa√m after a critical TGO thickness of ≈5 μm is reached. Consequently, interface damage is initially limited to short cracks within the YSZ material. As TGO thickness exceeds the critical threshold, multiple cracks originate within the TGO and join through the YSZ to form long delamination cracks. Joining is favoured by a simultaneous loss in YSZ strength, testified by a decrease in the nanomechanical properties (hardness, elastic modulus) of both high- and low-porosity top coats. This is due to microstructural changes occurring because of the continuous interplay between sintering and thermal shock cracking in the YSZ layers. Keywords: Thermal barrier coating, Fracture toughness, Nanohardness, High-speed nanoindentation, Thermal cycling fatiguehttp://www.sciencedirect.com/science/article/pii/S0264127519300528
collection DOAJ
language English
format Article
sources DOAJ
author Giovanni Bolelli
Maria Grazia Righi
Muhammad Zeeshan Mughal
Riccardo Moscatelli
Omar Ligabue
Nelso Antolotti
Marco Sebastiani
Luca Lusvarghi
Edoardo Bemporad
spellingShingle Giovanni Bolelli
Maria Grazia Righi
Muhammad Zeeshan Mughal
Riccardo Moscatelli
Omar Ligabue
Nelso Antolotti
Marco Sebastiani
Luca Lusvarghi
Edoardo Bemporad
Damage progression in thermal barrier coating systems during thermal cycling: A nano-mechanical assessment
Materials & Design
author_facet Giovanni Bolelli
Maria Grazia Righi
Muhammad Zeeshan Mughal
Riccardo Moscatelli
Omar Ligabue
Nelso Antolotti
Marco Sebastiani
Luca Lusvarghi
Edoardo Bemporad
author_sort Giovanni Bolelli
title Damage progression in thermal barrier coating systems during thermal cycling: A nano-mechanical assessment
title_short Damage progression in thermal barrier coating systems during thermal cycling: A nano-mechanical assessment
title_full Damage progression in thermal barrier coating systems during thermal cycling: A nano-mechanical assessment
title_fullStr Damage progression in thermal barrier coating systems during thermal cycling: A nano-mechanical assessment
title_full_unstemmed Damage progression in thermal barrier coating systems during thermal cycling: A nano-mechanical assessment
title_sort damage progression in thermal barrier coating systems during thermal cycling: a nano-mechanical assessment
publisher Elsevier
series Materials & Design
issn 0264-1275
publishDate 2019-03-01
description This paper studies how the nano-mechanical properties of thermal barrier coatings (TBCs) vary during thermal cycling, as a way to shed new light on their failure mechanisms. In particular, high-throughput nanoindentation revealed the evolution of hardness and elastic modulus distributions of plasma-sprayed yttria-stabilized zirconia (YSZ) top layers. The evolution of fracture toughness of the YSZ layers and the thermally grown oxide (TGO) formed onto the vacuum plasma-sprayed NiCoCrAlY bond coat were investigated by nanoindentation micro-pillar splitting.The TGO fracture toughness increases up to ≈2.5–3.5 MPa√m at the early stages of thermal cycling, followed by a rapid decrease to ≈2.0 MPa√m after a critical TGO thickness of ≈5 μm is reached. Consequently, interface damage is initially limited to short cracks within the YSZ material. As TGO thickness exceeds the critical threshold, multiple cracks originate within the TGO and join through the YSZ to form long delamination cracks. Joining is favoured by a simultaneous loss in YSZ strength, testified by a decrease in the nanomechanical properties (hardness, elastic modulus) of both high- and low-porosity top coats. This is due to microstructural changes occurring because of the continuous interplay between sintering and thermal shock cracking in the YSZ layers. Keywords: Thermal barrier coating, Fracture toughness, Nanohardness, High-speed nanoindentation, Thermal cycling fatigue
url http://www.sciencedirect.com/science/article/pii/S0264127519300528
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