Improved creep properties of Inconel 718 fabricated by selective laser melting from boron-phosphorus interaction

The inferior creep ductility of Inconel 718 (IN718) fabricated by selective laser melting (SLM), which is unable to meet aerospace material specification (≥4%), limits its engineering application. Despite persistent optimization efforts in the SLM process and post-heat treatment, this issue remains unresolved. This study involved SLM fabrication of the modified IN718 with trace amounts of LaB₆ and/or P, followed by homogenization and double aging heat treatment. The addition of trace LaB₆ notably influenced the recrystallized grain structure and carbide precipitation at grain boundaries, while trace P addition had minimal impact. All samples exhibited similar γ′ and γ^″ strengthening precipitates. Creep tests conducted at 650°C/690 MPa revealed that the individual modification of LaB₆ showed limited improvement in creep performance and P showed no improvement, but the combined addition of LaB₆ and P led to a substantial enhancement in creep performance, especially reaching as high as 8.6% creep strain. This remarkable improvement in creep ductility is unlikely to arise from the altered grain structure and grain boundary precipitates induced by LaB₆ but predominantly arises from the synergistic effect of P and B in enhancing resistance to crack propagation during the third stage of creep.