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741334 
Journal Article 
Reactive infiltration processing (RIP) of ultra high temperature ceramics (UHTC) into porous C/C composite tubes 
Jayaseelan, DD; De Sá, RG; Brown, P; Lee, WE 
2011 
Yes 
Journal of the European Ceramic Society
ISSN: 0955-2219 
31 
361-368 
WOS:000286084100015 
A novel reactive infiltration processing (RIP) technique was employed to infiltrate porous carbon fibre reinforced carbon (C/C) composite hollow tubes with ultra high temperature ceramic (UHTC) particles such as ZrB(2). The C/C composite tubes had initial porosity of similar to 60% with a bimodal (10 mu m and 100 mu m) pore size distribution. A slurry with 40-50% ZrB(2) solid loading particles was used to infiltrate the C/C tubes. Our approach combines in situ ZrB(2) formation with coating of fine ZrB(2) particles on carbon fibre surfaces by a reactive processing method. A Zr and B containing diphasic gel was first prepared using inorganic-organic hybrid precursors of zirconium oxychloride (ZrOCl(2)center dot 8H(2)O), boric acid, and phenolic resin as sources of zirconia, boron oxide, and carbon, respectively. Then commercially available ZrB(2) powder was added to this diphasic gel and milled for 6h. The resultant hybrid slurry was vacuum infiltrated into the porous hollow C/C tubes. The infiltrated tubes were dried and fired for 3 h at 1400 degrees C in flowing Ar atmosphere to form and coat ZrB(2) on the carbon fibres in situ by carbothermal reaction. Microstructural observation of infiltrated porous C/C composites revealed carbon fibres coating with fine nanosized (similar to 100 nm) ZrB(2) particles infiltrated to a depth exceeding 2 mm Ultra high temperature ablation testing for 60 s at 2190 degrees C suggested formation of ZrO(2) around the inner bore of the downstream surface. Crown Copyright (C ) 2010 Published by Elsevier Ltd. All rights reserved. 
Reactive infiltration processing; Carbothermal reaction; C/C composites; ZrB(2); Sol-gel; Vacuum infiltration; Ablation resistance 
Other
• Nanoscale Carbon