Abstract
Introducing a second phase has been an effective way to solve the brittleness of boron carbide (B(4)C) for its application. Though reduced graphene oxide (rGO) is an ideal candidate for reinforcing the B(4)C duo's two-dimensional structure and excellent mechanical properties, the toughness is less than 6 MPa·m(1/2), or the hardness is lower than 30 GPa in B(4)C-graphene composites. A barrier to enhancing toughness is the weak interface strength between rGO and B(4)C, which limits the bridging and pull-out toughening effects of rGO. In this work, internal stress was introduced using a high-pressure and high-temperature (HPHT) method with B(4)C-rGO composites. The optimal hardness and toughness values for the B(4)C-2 vol% rGO composite reached 30.1 GPa and 8.6 MPa·m(1/2), respectively. The improvement in toughness was 4 times higher than that of pure B(4)C. The internal stress in the composite increased gradually from 2.3 GPa to 3.3 GPa with an increase in rGO content from 1 vol% to 3 vol%. Crack deflection, bridging, and rGO pull-out are responsible for the improvement in toughness. Moreover, the high internal stress contributed to the formation of good interface strength by embedding rGO into the B(4)C matrix particles, which further enhanced the dissipation of the crack energy during the pull-out process and led to high toughness. This work provides new insights into synthesizing high-toughness B(4)C matrix composites.