Revealing thermally-activated nucleation pathways of diffusionless solid-to-solid transition

Solid-to-solid transitions usually occur via athermal nucleation pathways on pre-existing defects due to immense strain energy. However, the extent to which athermal nucleation persists under low strain energy comparable to the interface energy, and whether thermally-activated nucleation is still possible are mostly unknown. To address these questions, the microscopic observation of the transformation dynamics is a prerequisite. Using a charged colloidal system that allows the triggering of an fcc-to-bcc transition while enabling in-situ single-particle-level observation, we experimentally find both athermal and thermally-activated pathways controlled by the softness of the parent crystal. In particular, we reveal three new transition pathways: ingrain homogeneous nucleation driven by spontaneous dislocation generation, heterogeneous nucleation assisted by premelting grain boundaries, and wall-assisted growth. Our findings reveal the physical principles behind the system-dependent pathway selection and shed light on the control of solid-to-solid transitions through the parent phase's softness and defect landscape. Normally the diffusionless solid-to-solid transition between phases are driven by athermal processes, due to strain being overwhelmingly dominant. Here, the authors present a unique series of in-situ particle level observations of the solid-to-solid transition in colloidal particles suspended in a solvent, revealing new transition pathways.

Automated summary

Through microscopic observation, the study found that both athermal and thermally-activated pathways in solid-to-solid transitions are controlled by the softness of the parent crystal. Additionally, three new transition pathways were revealed: ingrain homogeneous nucleation, heterogeneous nucleation assisted by premelting grain boundaries, and wall-assisted growth.