A holistic mathematical modelling and simulation for cathodic delamination mechanism – a novel and an efficient approach

This source preferred by Zulfiqar Khan

Authors: Nazir, M.H., Khan, Z. and Stokes, K.

http://www.tandfonline.com/toc/tast20/current#.VTVAfWRVikr

Journal: Journal of Adhesion Science and Technology

Pages: 1-39

Publisher: Taylor & Francis

eISSN: 1568-5616

ISSN: 0169-4243

DOI: 10.1080/01694243.2015.1071023

This paper addresses a holistic mathematical design by using a novel approach for understanding the mechanism of cathodic delamination. The approach employed a set of interdependent parallel processes with each process representing: cation formation, oxygen reduction and cation transport mechanism respectively. Novel mathematical equations have been developed for each of the process based on the observations recorded from experimentation. These equations are than solved by using efficient time iterated algorithms. Each process consists of distinct algorithms which communicate with each other by using duplex channels carrying signals. Each signal represents a distinct delamination parameter. As a result of interdependency of various processes and their parallel behaviour; it is much easier to analyse the quantitative agreement between various delamination parameters. The developed modelling approach provides with an efficient and reliable prediction method for the delamination failure. The results obtained are in good agreement with the previously reported experimental interpretations and numerical results. This model provides a foundation for the future research within the area of coating failure analysis and prediction.

This data was imported from Scopus:

Authors: Nazir, M.H., Khan, Z.A. and Stokes, K.

Journal: Journal of Adhesion Science and Technology

Publisher: Taylor and Francis Ltd.

eISSN: 1568-5616

ISSN: 0169-4243

DOI: 10.1080/01694243.2015.1071023

This paper addresses a holistic mathematical design using a novel approach for understanding the mechanism of cathodic delamination. The approach employed a set of interdependent parallel processes with each process representing: cation formation, oxygen reduction and cation transport mechanism, respectively. Novel mathematical equations have been developed for each of the processes based on the observations recorded from experimentation. These equations are then solved using efficient time-iterated algorithms. Each process consists of distinct algorithms which communicate with each other using duplex channels carrying signals. Each signal represents a distinct delamination parameter. As a result of interdependency of various processes and their parallel behaviour, it is much easier to analyse the quantitative agreement between various delamination parameters. The developed modelling approach provides an efficient and reliable prediction method for the delamination failure. The results obtained are in good agreement with the previously reported experimental interpretations and numerical results. This model provides a foundation for the future research within the area of coating failure analysis and prediction.

This data was imported from Web of Science (Lite):

Authors: Nazir, M.H., Khan, Z.A. and Stokes, K.

Journal: JOURNAL OF ADHESION SCIENCE AND TECHNOLOGY

Volume: 29

Issue: 22

Pages: 2475-2513

eISSN: 1568-5616

ISSN: 0169-4243

DOI: 10.1080/01694243.2015.1071023

The data on this page was last updated at 04:55 on May 22, 2019.