Abstract
This paper presents novel results of research focused on reaction sintering of a mixture of expanded graphite and amorphous boron. It has been shown that as a result of combining the synthesis from the elements with sintering under pressure, dense boron carbide polycrystals (95% TD) can be obtained in which stable structures dominate, i.e., boron carbides of stoichiometry B13C2 and B4C. Sintering was carried out on boron excess systems, and reaction mixtures with the following mass ratios (B:C = 5:1; 10:1; and 15:1) were used. Boron excess systems were used due to the presence of additional carbon during sintering since the matrix, reactor lining, and heating elements were made of graphite. 1850 °C was considered to be the optimum reaction sintering temperature for all of the systems tested. This shows that a reduction in the sintering temperature of 200–300 °C was observed with respect to traditional sintering techniques. Micro-cracks are present in the sinters, the presence of which is most likely due to the difficulty in removing the gaseous products which accompany the boron carbide synthesis reaction. The elimination of these defects of sintering requires further research.
Highlights
Boron carbide is classified as a so-called covalent construction material
The rhombohedral boron carbide exhibits a wide range of phase homogeneity from the carbide with stoichiometry B10 C to the carbide with stoichiometry B4 C, with the most stable structures being those with high carbon content
The systems in reaction sintering tend to become more and more carbon saturated in the carbide structure [3]
Summary
Boron carbide is classified as a so-called covalent construction material. The strongB-B and B-C covalent bonding is the determining factor in the boron carbide structure.Boron carbide with a rhombohedral structure shows a wide range of phase homogeneity from B10.4 C Boron carbide is classified as a so-called covalent construction material. B-B and B-C covalent bonding is the determining factor in the boron carbide structure. Boron carbide with a rhombohedral structure shows a wide range of phase homogeneity from B10.4 C The carbon content of boron carbide significantly affects its properties and structure. Knowing the B/C ratio is crucial in the research devoted to this material. The lower limit of the boron carbide homogeneity range is difficult to specify [3,5].
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