Bulk MgB2 superconductor was synthesized from elemental Mg–B blends employing reactive forging (RF) - thermal explosion mode of self-propagating high-temperature synthesis - under a pressure of 200MPa. RF of the stoichiometric Mg–2B blend conducted at 800C yielded near-single-phase, but porous (92% TD), MgB2, whereas RF at 1000C produced a fully dense material containing significant amounts of MgO and MgB4. The addition of 20–30wt%Mg to the starting blend improved the consolidation behavior at 800C, as well as hindering the formation of MgB4 at 1000C. For all the compositions and RF conditions, the combustion temperature, TComb of approximately 1200C was measured. Plastic deformation at TComb of the ductile MgO phase and/or residual Mg resulted in full density consolidation of the synthesized material. In all the specimens, a superconducting transition was observed at 39K regardless of their porosity and the amount of second phases. Above 39K, the electrical resistivity of dense MgB2 specimens with residual metallic Mg was 30 times lower than that of the 92% dense near-single-phase MgB2.

Processing of Dense Bulk MgB2 Superconductor via Pressure-Assisted Thermal Explosion Mode of SHS. I.Zlotnikov, I.Gotman, E.Y.Gutmanas: Journal of the European Ceramic Society, 2005, 25[15], 3517-22