| Description |
1 online resource (xxv, 213 pages) : illustrations |
| Series |
Materials, circuits and devices series ; 70 |
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Materials, circuits and devices series ; 70.
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| Contents |
Intro; Contents; List of figures; List of tables; Preface; Acknowledgements; List of abbreviations; 1: Introduction; References; 2: Natural systems and processes; 2.1 Introduction; 2.2 Growth and functional adaptation; 2.3 Hierarchical structuring; 2.4 Natural self-cleaning and self-healing capabilities; 2.4.1 Self-cleaning; 2.4.2 Damage and repair healing; 2.4.3 Biological wound healing in skin; 2.5 Conclusions; References; 3: Theoretical models of healing mechanisms; 3.1 The first level models; 3.2 Example of modelling with finite element analysis (ANSYS code); 3.3 Third level models |
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4.6 Self-healing coatings for metallic structures references; 5: Self-healing evaluation techniques; 5.1 Methods with a three- and four-point bend test; 5.2 Tapered double-cantilever beam; 5.3 Compression after impact; 5.4 Combining the four-point bend test and acoustic emission; 5.5 Methods with dynamic impact; 5.5.1 Indentation test with a dropping mass; 5.5.2 High-speed ballistic projectile; 5.5.3 Hypervelocity impact; 5.6 Fibre Bragg grating sensors for self-healing detection; References; 6: Review of advanced fabrication processes; 6.1 Ruthenium Grubbs' catalyst |
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6.1.1 Pulsed laser deposition technique. 1.2 Experimental preparation of a ruthenium Grubbs' catalyst-pulsed laser deposition target; 6.1.3 Experimental results; 6.2 Healing capability of self-healing composites with embedded hollow fibres; 6.2.1 Detail of the capillary filling with healing agent; 6.2.2 Hollow fibres; 6.2.3 Capillary filling with ENB healing agent material; 6.2.4 Healing with hollow fibres; 6.3 Encapsulation of the ENB healing agent inside polymelamine-urea-formaldehyde shell; 6.3.1 Stability of ENB in poly-urea-formaldehyde shells |
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6.3.2 Preparation of ENB microcapsules with polymelamine-urea-formaldehyde shells; 6.3.3 Comparison of the open-air stability of the polyureaformaldehyde and polymelamine-urea-formaldehyde shells encapsulating ENB healing agent; 6.4 Integration of the ENB monomer with single-walled carbon nanotubes into a microvascular network configuration; 6.4.1 Experimental details; 6.4.2 Results and discussion; 6.4.3 Elaboration of the three-dimensional microvascular network and self-healing testing; References; 7: Self-healing in space environment |
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7.1 Challenges of the self-healing reaction in the space environment |
| Summary |
This book addresses the key concepts of self-healing processes, from their occurrences in nature through to recent advances in academic and industrial research. It includes a detailed description and explanation of a wide range of materials and applications such as polymeric, anticorrosion, smart paints, and carbon nanotubes |
| Analysis |
fibre sensors |
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COPV |
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orbital space debris simulation |
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impact tests |
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space environment |
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advanced fabrication processes |
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composites |
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polymers |
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finite element analysis |
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healing mechanisms |
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natural processes |
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natural systems |
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self-healing materials |
| Bibliography |
Includes bibliographical references and index |
| Notes |
Online resource; title from PDF title page (EBSCO, viewed September 10, 2019) |
| Subject |
Self-healing materials.
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Biomimetics.
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Optical fiber detectors.
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Polymers.
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polymers.
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Self-healing materials
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Biomimetics
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Optical fiber detectors
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Polymers
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aerospace materials.
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biomimetics.
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composite materials.
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fibre optic sensors.
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impact testing.
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intelligent materials.
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materials preparation.
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polymers.
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space debris.
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| Form |
Electronic book
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| Author |
Haddad, Emile I., author.
|
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Jamroz, Wes R., author.
|
| ISBN |
9781785619939 |
|
1785619934 |
|
1523125195 |
|
9781523125197 |
|
