Showing 3 results for Rajabi
M. Ghavidel, S. M. Rabiee, M. Rajabi,
Volume 11, Issue 1 (march 2014)
Abstract
In this study, porous titanium composites containing 5, 10 and 15 wt. % nanobioglass were fabricated by
space holder sintering process. The pore morphology and phase constituents of the porous samples were characterized
by X-ray diffractometry (XRD) and scanning electron microscopy (SEM). The mechanical properties were determined
by compression test. The porosity of the sintered samples showed an upward trend with an increase in bioglass content.
As the bioglass content was increased, the compressive strength was first increased and then decreased. The results
obtained in this work suggest that the fabricated porous compact with 10 wt. % bioglass with compressive strength
value of about 76.7 MPa, high porosity and good biocompatibility has the potential application for bone tissue
engineering.
M. Maddah, M. Rajabi, S. M. Rabiee,
Volume 12, Issue 4 (December 2015)
Abstract
In this study, the composite material with composition of MgH2-5 wt% SiC has been prepared by co-milling of MgH2 with SiC powder. The effect of milling time and additive on MgH2 structure, i.e. crystallite size, lattice strain, particle size and specific surface area, and also hydrogen desorption properties of obtained composite was evaluated by thermal analyzer method and compared with pure un-milled MgH2. The phase constituents and grain size of powder were characterized by X-ray diffractometry method. It has been shown that addition of 5 wt% SiC to MgH2 and mechanical alloying up to 30 h formed a nanocrystalline composite with the average crystallite size of 12 nm, average particle size of 0.5 µm and specific surface area of 10 m2/g. On the other hand, SiC can help to break up particles and reduce the particle size. As a consequence, the desorption temperature of composite material milled for 30 h has decreased from 435 °C to 361 °C.
Zahra Rajabimashhadi, Rahim Naghizadeh,
Volume 19, Issue 1 (March 2022)
Abstract
ꞵ-tricalcium phosphate (ꞵ-TCP) and anorthite are the main crystalline components in bone china bodies. The difference in their thermal expansion coefficients causes a decrease in the thermal shock resistance of the body. In this study, anorthite was replaced with bone ash at the bone china body, and the effect of this new composition on different properties of bone china, after curing at 1260 °C for 3 hours, was investigated. The results showed that the physical and mechanical properties of the sample containing 50 wt% anorthite compared to the typical bone china improved and only 8.7% of the whiteness index diminished. Also the microstructure of samples containing Anorthite were observed without thermal crack and almost uniform distribution of Anorthite and quartz crystals in the heterogeneous glass matrix.