Affiliation:
1. Chair of Structural Analysis Helmut Schmidt University/University of the Federal Armed Forces Hamburg Germany
2. Institute for Materials Science Helmut Schmidt University/University of the Federal Armed Forces Hamburg Germany
3. Brunel Centre for Advanced Solidification Technology Brunel University London Uxbridge UK
Abstract
AbstractAerosol deposition (AD) enables the formation of dense ceramic coatings by high velocity impact of submicron‐sized particles. However, up to now, it is still not clear how the material properties of the ceramic powder particles influence their impact behavior and possible success in layer build‐up in AD. Therefore, in order to provide a broader understanding, this study utilizes molecular dynamic (MD) simulations to investigate the impacts of single‐crystalline particles while manipulating binding energies, particle sizes, and impact velocities, addressing a rather wide range of different materials and process conditions. The findings reveal that increasing binding energies from 0.22 to 0.96 eV necessitates up to three times higher velocities to reach thresholds for bonding and fragmentation, which are linked to potential layer formation. For conditions above the velocity thresholds given by individual binding energies, similarities in the deformation and fragmentation patterns are derived. Consequently, rough estimations regarding the required particle impact velocities for AD of different materials can be inferred.
Subject
Electrical and Electronic Engineering,Atomic and Molecular Physics, and Optics
Reference8 articles.
1. Aerosol Deposition Method for Fabrication of Nano Crystal Ceramic Layer
2. Room Temperature Impact Consolidation (RTIC) of Fine Ceramic Powder by Aerosol Deposition Method and Applications to Microdevices
3. A numerical study on planar gradient acoustic impedance matching for guided ultrasonic wave detection;Rottmann M.;Journal of Vibration and Control,2023
4. An overview of the aerosol deposition method: process fundamentals and new trends in materials applications;Hanft D.;Journal of Ceramic Science and Technology,2015
5. Features of ceramic nanoparticle deformation in aerosol deposition explored by molecular dynamics simulation