A Kinetic Phase-Field Model of Diffusion Bonding: A Nonlocal Approach to Interface Coalescence

Abstract Conventional phase-field models often drive solid-solid interfaces to merge when in close proximity. This limits their use for processes like diffusion bonding, where interfaces might need to remain distinct under certain conditions. We propose a phase-field model to address this. Our model modifies the kinetic evolution equation using a physically-motivated geometric criterion to control interface merging. This criterion, based on nonlocal higher-derivative curvature invariants of the phase field, can be temperature-dependent. It acts as a potential barrier, allowing a range of behaviors from complete fusion to the preservation of distinct boundaries. Our approach is thermodynamically consistent and can be linked to sharp-interface limits through asymptotic analysis. Simulations show controlled bonding kinetics, demonstrating capabilities not available with existing methods for modeling interfaces that must remain distinct below specific thermodynamic thresholds.