摘要
The understanding of temperature and time-dependent metal borides precipitation/dissolution is crucial for the design of the transient liquid phase(TLP)bonding process of Ni-based alloys.It however remains elusive despite substantial research efforts for many years mainly owing to the uncertainty on the precipitated metal borides and the complex thermo-kinetics in the process.In this paper,we have unambiguously constructed the micro/nano scale map of the precipitated metal borides in the TLP bonded Ni-based Inconel 718 superalloy via a high-throughput transmission electron microscopy(TEM)analysis.Five types of metal borides were found to precipitate in the diffusion affected zone(DAZ)when the isothermal solidification is completed.They are the M_(5)B_(3)with stacking faults,Ti-rich M_(3)B4,and Nb-rich M_(3)B4 at the grain boundaries as well as single-crystalline M_(5)B_(3)and M_(3)B2 inside the grains.Notably,the crystal structure of the faulted M_(5)B_(3)was rationalized by a hybrid modelling approach integrating firstprinciples calculation and TEM experiments.The sublattice model,with the optimized thermodynamic model parameters,was used to reproduce the metal borides precipitation map in the TLP process using DICTRA software.Coupling with multiscale simulation and experimental data,the present work built a modified thermo-kinetic model,which enables the design of the TLP bonding process of Ni-based alloys that often involves complicated time-tempe rature schedules and the precipitation/dissolution of a variety of diffe rent phases.The strategy can be applied to the design of the brazing process of other alloys or hybrid materials such as ceramics and metal.
基金
financially supported by the National Supercomputing Centre Singapore for the use of its high-performance computing facilities
the financial support from grant A1898b0043 sponsored by the Agency for Science,Technology and Research(ASTAR),Singapore
the financial support from ASTAR Metal Alloy Design and Synthesis program(SC25/18-8R1715-PRJ1)。
