Study on the microstructure and mechanical properties of friction stir processed aluminum matrix composite strengthened by in-situ formed Al2O3 particle and Al-Ce intermetallic compound

• Main Authors: Chin-Fu Chen, 陳金福
• Other Authors: Po-We Kao
• Format: Others
• Language: en_US
• Published: 2010
• Online Access: http://ndltd.ncl.edu.tw/handle/92384417546301402461

博士 === 國立中山大學 === 材料與光電科學學系研究所 === 98 === In this study, a novel technique was used to produce aluminum based in situ composites from powder mixtures of Al and CeO2. This technique has combined hot working nature of friction stir processing (FSP) and exothermic reaction between Al and oxide. Billet of powder mixtures was prepared by the use of conventional pressing and sintering route. The sintered billet was then subjected to multiple passages of friction stir processing (FSP). The microstructure was characterized by the use of TEM, SEM and XRD. The reinforcing phases were identified as Al11Ce3 and δ*-Al2O3. The Al2O3 particles with an average size of ~10 nm are uniformly distributed in the aluminum matrix, which has an average grain size about 390-500 nm. The analysis of TEM indicated that these Al2O3 particles exhibit crystallographic orientation relationship with the aluminum matrix, i.e., (223)δ*-Al2O3//(111)Al and [1-10]δ*-Al2O3 roughly parallel to [1-10]Al. The precipitates of Al2O3 exhibiting crystallographic orientation relationship with the aluminum clearly indicates that they were formed from solid state precipitation. Apparently, significant supersaturation of oxygen in aluminum had been created in FSP, and nanometric Al2O3 particles were then precipitated uniformly in the aluminum matrix. This study shows that both sintering temperature and the tool traversing speed used in FSP have significant influence on the microstructure and mechanical properties of the composite. The composites produced exhibit high strength both at ambient and elevated temperatures. For example, the composite produced by 833K sintering followed by FSP with tool traversing speed of 30 mm/min possesses enhanced modulus (E = 109 GPa) and strength (UTS = 488 MPa) as well as a tensile ductility of ~3%. The major contributions to the high strength of the composite are the submicrometer grain structure of aluminum matrix and the Orowan strengthening caused by the fine dispersion of nanometer size Al2O3 particles inside aluminum grains. In addition, the composite also exhibits high strength at elevated temperatures up to 773 K. The good thermal stability and high temperature strength of the composite may be attributed to the uniform dispersion of nanometric Al2O3 particles, which are very stable at elevated temperatures.