Interfacial Phenomena in Adhesion and Adhesive Bonding.
Saved in:
| : | |
|---|---|
| TeilnehmendeR: | |
| Place / Publishing House: | Singapore : : Springer Singapore Pte. Limited,, 2023. ©2024. |
| Year of Publication: | 2023 |
| Edition: | 1st ed. |
| Language: | English |
| Online Access: | |
| Physical Description: | 1 online resource (368 pages) |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
Table of Contents:
- Intro
- Preface
- Contents
- Abbreviations
- Introduction-Interfaces in Adhesion and Adhesive Bonding
- 1 Social Background of Research on Adhesion and Adhesive Bonding
- 2 Interphase in Adhesive Bonding
- 3 Testing of Adhesion and Adhesive Bonding
- 4 Multiscale and Hierarchical Structures in the Interphase and Interfacial Region in Adhesive Bonding
- 5 Visualization and Analysis of Interphases in Adhesion and Adhesive Bonding
- References
- Electron Microscopy for Visualization of Interfaces in Adhesion and Adhesive Bonding
- 1 Instrumentation of Electron Microscopy
- 2 Analytical Electron Microscopy-EDX and EELS
- 3 Specimen Preparation
- 3.1 Preparation of Thin Sections by Ultramicrotomy
- 3.2 Staining
- 3.3 Focused Ion Beam Fabrication (FIB)
- 3.4 Surface Replica
- 4 EFTEM
- 4.1 Electron Spectroscopic Imaging (ESI) and Parallel EELS
- 4.2 Elemental Mapping and Image-EELS
- 5 STEM
- 5.1 Spectrum Imaging (SI) with Simultaneous EELS and EDX
- 5.2 ELNES Phase Mapping
- 5.3 Tomography and 3D Elemental Mapping
- 6 SEM
- 6.1 Energy-Filtered SE Imaging
- 6.2 Correlative Raman Imaging and SEM
- 7 In Situ TEM
- 8 Specimen Damages by Electron Beam Irradiation
- 8.1 Mass Loss in Polymer Thin Sections
- 8.2 Chemical Damages of Polymers Evaluated by ELNES
- 8.3 Electron-Induced Contamination
- 9 Conclusions
- References
- Interfacial Phenomena in Adhesion and Adhesive Bonding Investigated by Electron Microscopy
- 1 Visualization of Homopolymer/Random Copolymer Interfaces by EFTEM
- 2 Thermodynamic Acceleration of Interdiffusion in Miscible Polymer Pairs
- 3 Role of Interfacial Entanglements on Interfacial Toughness Studied by Nanofractography
- 3.1 Interfacial Thickness and Toughness in PMMA/SAN Interfaces
- 3.2 Interfacial Entanglements at PS/PS Welded Interfaces.
- 3.3 Mechanism of Low-Temperature Bonding of VUV-Activated COP
- 4 Adhesive Bonding by Surface and Interface Modifications of Polypropylene-Effect of Chemical Bonding and Mechanical Interlocking
- 5 Formation of the Interphase Between Aluminum and Polypropylene-The Role of Reactive Functionality on Metal Bonding
- 5.1 Bonding Mechanism Investigated by Replica-STEM Tomography
- 5.2 Mechanism of Interphase Formation
- 6 Mechanism of Adhesive Bonding of Aluminum Alloys Studied by STEM-EELS/ELNES
- 6.1 Mechanism of Steam Treatment in Improving Adhesion Bonding of Aluminum
- 6.2 Role of the Chemical Bonding on Interfacial Toughness Between Aluminum and Epoxy Adhesive
- 7 Metal-plastic Direct Bonding by Injection Nano-Molding-Interfacial Structures and Testing Joint Performance
- 8 Toughness and Durability of Interfaces in Dissimilar Adhesive Joints of Aluminum and Carbon-Fiber Reinforced Thermoplastics
- 8.1 Evaluation of Interfacial Fracture Toughness by ADCB Test
- 8.2 Evaluation of Durability of Adhesive Interfaces Under High Humidity Environment by Wedge Test
- 8.3 Stress-Induced Corrosion at Adhesive Interfaces
- 9 Concluding Remark
- References
- Direct Visualization of Mechanical Behavior During Adhesive Bonding Failure Using Mechanoluminescence (ML)
- 1 Introduction of Mechanoluminescence-Materials, Sensor and Sensing Concept
- 2 Mechanoluminescence (ML) Technology-Visualization of the Dynamic Strain Information
- 2.1 Mechanoluminescence (ML) Materials
- 2.2 Mechanoluminescence (ML) Sensors
- 3 Killer Application of Mechanoluminescence 1: Detection of Crack and Defects in Structural Health Monitoring (SHM)
- 3.1 Mechanoluminescence (ML) Detection of the Origin to Deduce the Integrity
- 3.2 Mechanoluminescence (ML) Sensing in Real Infrastructures
- 3.3 Visualization of Repair Effect Using Mechanoluminescence (ML).
- 4 Killer Application of Mechanoluminescence 2: Innovation in Design and Prediction
- 4.1 Mechanoluminescence (ML) Sensing in CFRP Composite Material
- 4.2 Simulation Sophistication Using Mechanoluminescence (ML)
- 5 Mechanoluminescent (ML) Visualization in the Evaluation of Adhesive Joint
- 5.1 Fracture Toughness for Crack Propagation
- 5.2 Tensile Shear Strength (TSS) Test of Adhesive Joint
- 5.3 Cross-Tension Strength (CTS) Test of Adhesive Joint
- 5.4 Mapping of Weak Bond and Local Fracture Toughness
- 6 New Challenge for the Invisible Information on the Lightweight Structure
- 6.1 Toward the Appropriate Choice of Joints in the Multi-material Concept
- 6.2 Static Electricity in Light Weighting Structure
- 7 Concluding Remark
- References
- Analysis of Molecular Surface/Interfacial Layer by Sum-Frequency Generation (SFG) Spectroscopy
- 1 Introduction
- 2 Basic Theory for Surface/Interface Sum-Frequency Generation
- 3 Experimental Equipment
- 3.1 General Description of the Experimental Equipment
- 3.2 SFG Spectroscopy with Narrowband Input
- 3.3 SFG Spectroscopy with a Broadband Input
- 3.4 Doubly-Resonant Sum-Frequency Generation Spectrometer
- 3.5 Experimental Conditions for Polymeric Material Surfaces and Adhesive Interfaces
- 4 Applications of SFG Spectroscopy to Study Polymeric Materials Surfaces and Interfaces
- 4.1 Chemical Structure of Adherent Surfaces
- 5 Investigation of Buried Polymer/polymer Interfaces
- 6 Probing Adhesive Interfaces
- 6.1 Polyurethane Adhesives
- 6.2 Silyl-Terminated Polyether Adhesives
- 7 Metal/polymer Interfaces
- 8 Bio-adhesive Interfaces
- 9 Molecular Conformation at the Liquid Interfaces
- 10 Molecular Conformation at the Organic Device Interfaces
- 11 Comprehensive Study of Adhesive Interfaces Combining SFG with Other Techniques.
- 11.1 Acid-Base Interaction at the Epoxy Adhesive/AlOx Interface
- 11.2 Formation of Covalent Bonds
- 11.3 Ordering of Functional Group at AlOx Interface
- 11.4 Interaction Between Surface O-H Bonds and Adsorbates
- 12 Summary and Outlook
- References.