Litcius/Paper detail

An atomic layer deposition diffusion–reaction model for porous media with different particle geometries

Niko Heikkinen, Juha Lehtonen, Riikka L. Puurunen

2024Physical Chemistry Chemical Physics12 citationsDOIOpen Access PDF

Abstract

This work presents a diffusion-reaction model for atomic layer deposition (ALD), which has been adapted to describe radial direction reactant transport and adsorption kinetics in a porous particle. Specifically, we present the effect of three particle geometries: spherical, cylindrical and a slab in the diffusion-reaction model. The reactant diffusion propagates as a unidimensional front inside the slab particle, whereas with cylinder and spherical particles, the reactant diffusion approaches the particle centre from two and three dimensions, respectively. Due to additional reactant propagation dimensions, cylindrical and spherical particles require less exposure for full particle penetration. In addition to the particle geometry effect, a sensitivity analysis was used to compare the impact of the particles' physical properties on the achieved penetration depth. The analysis evaluates properties, such as the combined porosity and tortuosity factor, mean pore diameter, specific surface area, pore volume, and particle radius. Furthermore, we address the impact of the reactant molar mass, growth-per-cycle (GPC), sticking probability, reactant exposure and deposition temperature on the simulated diffusion and surface coverage profiles. The diffusion-reaction model presented in this work is relevant for the design and optimization of ALD processes in porous media with different particle geometries.

Topics & Concepts

Atomic layer depositionDeposition (geology)DiffusionLayer (electronics)Particle (ecology)PorosityMaterials sciencePorous mediumChemical engineeringParticle depositionChemical physicsChemistryNanotechnologyThermodynamicsComposite materialPhysicsGeologyEngineeringSedimentPaleontologyOceanographySemiconductor materials and devicesCatalytic Processes in Materials ScienceElectronic and Structural Properties of Oxides