Design of Desintering in Tin Dioxide Nanoparticles

Controlling sintering is a critical aspect for the processing of dense parts and to improve stability of nanoparticles. Dopants are typically used for this purpose, but the extension of the role of dopants in the phenomena is still not completely understood. In this work we demonstrate the possibility of inducing desintering in a ceramic system by programming a dopant redistribution during heat treatment. Tin dioxide doped with manganese was sintered up to intermediate densities and density was decreased afterward by exposing the sample to a lower temperature. A change in the oxidation state and ionic radius of manganese caused it to segregate at high temperatures and to partially redissolve in the crystal at a lower one. This interfacial chemistry change caused a decrease of the dihedral angle at lower temperature, creating a driving force for porosity volume increase (dedensification) by mass flow against curvature potential. The result is predictable from extrapolations of pore stability theories but never directly demonstrated, and may explain why some doped systems do not follow regular sintering predictions, i.e. interfacial chemistry and energetics can change during processing, affecting driving forces.