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A Phenomenological Mathematical Modelling Framework for the Degradation of Bioresorbable CompositesDegradation of Bioresorbable Composites: Tricalcium Phosphate Case Studies

A Phenomenological Mathematical Modelling Framework for the Degradation of Bioresorbable... [As previously mentioned in the introductory chapter, studying the degradation of biocomposites is a time and resource-consuming process. Therefore it is logical to try and maximise the information that can be extracted from already published experimental data. Although inaccurate and incomplete information in composite characterisation are to be expected, analysing these published degradation data with the computational models obtained from the general modelling framework based on an extended version of Pan et al.’s TCP-polyester composite degradation model [1] and presented in Chap. 3 is, in the author’s opinion, still a worthy approach. By doing so, a global degradation map for biocomposites can be built. This map, albeit incomplete, will aid understanding of the biocomposite degradation mechanisms and highlight areas of particular interest due to their appropriate degradation profiles.] http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png

A Phenomenological Mathematical Modelling Framework for the Degradation of Bioresorbable CompositesDegradation of Bioresorbable Composites: Tricalcium Phosphate Case Studies

Part of the Springer Theses Book Series
Moreno-Gomez, Ismael
Springer Journals — Apr 6, 2019
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Publisher
Springer International Publishing
Copyright
© Springer Nature Switzerland AG 2019
ISBN
978-3-030-04989-8
Pages
89 –150
DOI
10.1007/978-3-030-04990-4_4
Publisher site
See Chapter on Publisher Site

Abstract

[As previously mentioned in the introductory chapter, studying the degradation of biocomposites is a time and resource-consuming process. Therefore it is logical to try and maximise the information that can be extracted from already published experimental data. Although inaccurate and incomplete information in composite characterisation are to be expected, analysing these published degradation data with the computational models obtained from the general modelling framework based on an extended version of Pan et al.’s TCP-polyester composite degradation model [1] and presented in Chap. 3 is, in the author’s opinion, still a worthy approach. By doing so, a global degradation map for biocomposites can be built. This map, albeit incomplete, will aid understanding of the biocomposite degradation mechanisms and highlight areas of particular interest due to their appropriate degradation profiles.]

Published: Apr 6, 2019

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