Design of long-term ablation protective Zr0.92Ta0.04Si0.04O2 coating via large lattice distortion and limited phase precipitation

Dou Hu; Xiaoxuan Li; Songlin Chen; Yutai Zhang; Zhe Fan; Kefei Yan; Qiangang Fu

doi:10.1016/j.corsci.2025.112689

Design of long-term ablation protective Zr_0.92Ta_0.04Si_0.04O₂ coating via large lattice distortion and limited phase precipitation

Dou Hu, Xiaoxuan Li, Songlin Chen, Yutai Zhang, Zhe Fan, Kefei Yan, Qiangang Fu

School of Materials Sience and Engineering

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

Thermally sprayed Zr-Ta-Si-O coatings were investigated to overcome the oxygen blocking limitations of traditionally self-derived porous ZrO₂ layer. The individual solid solution of Ta and Si into ZrO₂ lattice was respectively found trapped in the rapid phase precipitation and volatile loss, thus exhibiting insufficient ablation property. The as-designed Zr_0.92Ta_0.04Si_0.04O₂ coating successfully acquired a near-zero linear recession rate (-0.10 μm/s) after 900 s cyclic ablation (2.4 MW/m², 15 cycles). Key reasons can be attributed to a continuous sintering promotion and secondary phase precipitation limitation via large lattice distortion, where that of Zr_7/8Ta_1/16Si_1/16O₂ lattice exhibits over 200 % increase than Zr_7/8Ta_1/8O₂ lattice.

Original language	English
Article number	112689
Journal	Corrosion Science
Volume	245
DOIs	https://doi.org/10.1016/j.corsci.2025.112689
State	Published - 1 Apr 2025

Keywords

Anti-ablation coating
C/C composites
Thermal spray
UHTC
Zr-Ta-Si-O

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10.1016/j.corsci.2025.112689

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title = "Design of long-term ablation protective Zr0.92Ta0.04Si0.04O2 coating via large lattice distortion and limited phase precipitation",

abstract = "Thermally sprayed Zr-Ta-Si-O coatings were investigated to overcome the oxygen blocking limitations of traditionally self-derived porous ZrO2 layer. The individual solid solution of Ta and Si into ZrO2 lattice was respectively found trapped in the rapid phase precipitation and volatile loss, thus exhibiting insufficient ablation property. The as-designed Zr0.92Ta0.04Si0.04O2 coating successfully acquired a near-zero linear recession rate (-0.10 μm/s) after 900 s cyclic ablation (2.4 MW/m2, 15 cycles). Key reasons can be attributed to a continuous sintering promotion and secondary phase precipitation limitation via large lattice distortion, where that of Zr7/8Ta1/16Si1/16O2 lattice exhibits over 200 % increase than Zr7/8Ta1/8O2 lattice.",

keywords = "Anti-ablation coating, C/C composites, Thermal spray, UHTC, Zr-Ta-Si-O",

author = "Dou Hu and Xiaoxuan Li and Songlin Chen and Yutai Zhang and Zhe Fan and Kefei Yan and Qiangang Fu",

note = "Publisher Copyright: {\textcopyright} 2025 Elsevier Ltd",

year = "2025",

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day = "1",

doi = "10.1016/j.corsci.2025.112689",

language = "英语",

volume = "245",

journal = "Corrosion Science",

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TY - JOUR

T1 - Design of long-term ablation protective Zr0.92Ta0.04Si0.04O2 coating via large lattice distortion and limited phase precipitation

AU - Hu, Dou

AU - Li, Xiaoxuan

AU - Chen, Songlin

AU - Zhang, Yutai

AU - Fan, Zhe

AU - Yan, Kefei

AU - Fu, Qiangang

PY - 2025/4/1

Y1 - 2025/4/1

N2 - Thermally sprayed Zr-Ta-Si-O coatings were investigated to overcome the oxygen blocking limitations of traditionally self-derived porous ZrO2 layer. The individual solid solution of Ta and Si into ZrO2 lattice was respectively found trapped in the rapid phase precipitation and volatile loss, thus exhibiting insufficient ablation property. The as-designed Zr0.92Ta0.04Si0.04O2 coating successfully acquired a near-zero linear recession rate (-0.10 μm/s) after 900 s cyclic ablation (2.4 MW/m2, 15 cycles). Key reasons can be attributed to a continuous sintering promotion and secondary phase precipitation limitation via large lattice distortion, where that of Zr7/8Ta1/16Si1/16O2 lattice exhibits over 200 % increase than Zr7/8Ta1/8O2 lattice.

AB - Thermally sprayed Zr-Ta-Si-O coatings were investigated to overcome the oxygen blocking limitations of traditionally self-derived porous ZrO2 layer. The individual solid solution of Ta and Si into ZrO2 lattice was respectively found trapped in the rapid phase precipitation and volatile loss, thus exhibiting insufficient ablation property. The as-designed Zr0.92Ta0.04Si0.04O2 coating successfully acquired a near-zero linear recession rate (-0.10 μm/s) after 900 s cyclic ablation (2.4 MW/m2, 15 cycles). Key reasons can be attributed to a continuous sintering promotion and secondary phase precipitation limitation via large lattice distortion, where that of Zr7/8Ta1/16Si1/16O2 lattice exhibits over 200 % increase than Zr7/8Ta1/8O2 lattice.

KW - Anti-ablation coating

KW - C/C composites

KW - Thermal spray

KW - UHTC

KW - Zr-Ta-Si-O

UR - http://www.scopus.com/inward/record.url?scp=85214491341&partnerID=8YFLogxK

U2 - 10.1016/j.corsci.2025.112689

DO - 10.1016/j.corsci.2025.112689

M3 - 文章

AN - SCOPUS:85214491341

SN - 0010-938X

VL - 245

JO - Corrosion Science

JF - Corrosion Science

M1 - 112689

ER -

Design of long-term ablation protective Zr_0.92Ta_0.04Si_0.04O₂ coating via large lattice distortion and limited phase precipitation

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Keywords

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