Fabrication of conductive porous alumina (CPA) structurally modified with carbon nanotubes (CNT)

Added CNT, nano-carbon networks (NCN, converted from polymer networks by reductive sintering) with graphitic structure and Al2O3 grains form ternary composite (CNT/NCN/Al2O3). [Display omitted] ► Uniform dispersion of CNT in ternary composite. ► Enhanced flexural strength of ternary composite. ► Non...

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Bibliographic Details
Published in:Advanced powder technology : the international journal of the Society of Powder Technology, Japan Japan, 2013-09, Vol.24 (5), p.824-828
Main Authors: Hai, Chunxi, Shirai, Takashi, Fuji, Masayoshi
Format: Article
Language:English
Subjects:
Al2O3
Composite
Gelcasting
Nano-carbon networks (NCNs)
Reductive sintering
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Summary:Added CNT, nano-carbon networks (NCN, converted from polymer networks by reductive sintering) with graphitic structure and Al2O3 grains form ternary composite (CNT/NCN/Al2O3). [Display omitted] ► Uniform dispersion of CNT in ternary composite. ► Enhanced flexural strength of ternary composite. ► Non-destruction of CNTs via high temperature reductive sintering but further graphitilization. ► Unique 3-dimensional CNT/NCN graphitic filler and alumina matrix structure. A novel binary porous composite nano-carbon networks (NCNs)/alumina, which is denoted as electrically conductive porous alumina (CPA), was structurally modified by carbon nanotubes (CNT) pre-treated with mixed concentrated acids at 60°C for 6h in this study. This conductive ceramics (CCs) was fabricated by combination of gelcasting and high temperature reductive sintering (HTRS) in novel atmosphere. CNT pre-treatment leading to the increased hydrophilicity makes it possible to make uniformly dispersed CNT/alumina slurry. And by HTRS in Ar at 1700°C for 2h, well-gelled polymer net-paths in green body prepared by gelcasting technology were totally converted to nano-carbon networks (NCNs) without destruction of CNT. NCN with graphitic crystal structure was evaluated by Raman spectroscopy in sintered ceramic body. Moreover, comparing with as-received CNT, the decreased surface defect of detected composite also supported the further graphitization of CNT via HTRS in Ar instead of burning out. With the aid of field-emission scanning electronic microscopy (FE-SEM) observation, the increased alumina grains in sintered ceramic body CNT/NCN/alumina was valid. Moreover, it was demonstrated that there were three components in this composite, which is carbon filler with two different forms (CNT and NCN) and alumina matrix. And these three components CNT covered with Al2O3 particles (Al2O3/CNT), NCN and alumina grains (alumina) co-exist in four different situations as follows: (a) Al2O3/CNT–alumina co-junction, (b) Al2O3/CNT–NCN co-junction, (c) Al2O3/CNT–alumina–NCN and (d) Al2O3/CNT mesh between alumina boundaries. Furthermore, by comparing with binary composite NCN/alumina (CPA), the increased flexural strength of ternary composite CNT/NCN/alumina (CNT/CPA) up to 38MPa was attributed to the reinforcement CNT acting as elastic bridge in composite.
ISSN:0921-8831
1568-5527
DOI:10.1016/j.apt.2012.12.012