Development of a DEM taking account of neck increments caused by surface diffusion for sintering and application to analysis of the initial stage of sintering

Development of a DEM taking account of neck increments caused by surface diffusion for sintering and application to analysis of the initial stage of sintering

[Display omitted] •A DEM taking into account neck increments caused by surface diffusion was newly developed.•The neck growth rate caused by surface diffusion was able to be determined by using the FDM.•Surface diffusion is effective at restricting the enlargement of the initial inhomogeneity. A dis...

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Bibliographic Details
Published in:Computational materials science Vol. 196; p. 110525
Main Author: Matsuda, Tetsushi
Format: Journal Article
Language:English
Published: Elsevier B.V 01-08-2021
Subjects:
Finite-difference modeling
Grain boundary diffusion
Simulation
Sintering
Grain boundary diffusion
Simulation
Finite-difference modeling
Sintering
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Summary:[Display omitted] •A DEM taking into account neck increments caused by surface diffusion was newly developed.•The neck growth rate caused by surface diffusion was able to be determined by using the FDM.•Surface diffusion is effective at restricting the enlargement of the initial inhomogeneity. A discrete element model (DEM) capable of handling changing temperatures was newly developed for simulating sintering phenomena. The neck growth rate caused by surface diffusion was determined using a finite-difference model (FDM). The developed DEM was applied to clarify the effects of surface diffusion on the shrinkage behavior. The simulation results indicated that surface diffusion suppressed the local shrinkage through neck growth; on the other hand, the simulation excluding surface diffusion showed rapid local shrinkage. As a result, some cavities were enlarged when surface diffusion was not taken into consideration. It is known that surface diffusion reduces the driving force for shrinkage; however, it was revealed that surface diffusion has advantages in restricting the growth of inhomogeneity during the initial stage of sintering, which was expected to reduce pores at the end of sintering.
ISSN:0927-0256
1879-0801
DOI:10.1016/j.commatsci.2021.110525