Foreword -- Preface -- 1 Fundamentals of Smart Corrosion Protection Coatings -- 1.1 Introduction of Corrosion Protection Coatings -- 1.1.1 Mechanisms of Corrosion Protection Coatings -- 1.1.2 Failure Type and Failure Mechanism of Corrosion Protection Coatings -- 1.2 Smart Self-healing Coatings -- 1.2.1 Intrinsic Self-healing Coating -- 1.2.1.1 Self-healing Based on Dynamic Bonds -- 1.2.1.2 Self-healing Based on Shape Memory Effect -- 1.2.2 Extrinsic Self-healing Coating -- 1.2.2.1 Self-healing Coating Based on Defect Filling -- 1.2.3 Characterization Methods of Self-healing Properties -- 1.3 Smart Self-reporting Coatings -- 1.4 Superhydrophobic Coatings -- 1.5 Conclusions -- References -- 2 Development of Thermally Activated Self-healing Coating -- 2.1 Introduction -- 2.2 Thermally Activated Self-healing Coatings to Simultaneously Recover the Corrosion-resistance and Adhesion Strength -- 2.3 Thermally Activated Self-healing Coatings Based on Dual Actions -- 2.4 Chapter Summary -- References -- 3 Development of Photothermally Activated Self-healing Coating -- 3.1 Introduction -- 3.2 Self-healing Coating Based on GO-CeO 2 Photothermal Fillers -- 3.3 Self-healing Coating Based on TiN-BTA@MSN Photothermal Filler -- 3.4 Self-healing Coating Based on PCL@TiN Photothermal Fillers -- 3.5 Self-healing Coating Based on Fe 3 O 4 -MBT Photothermal Fillers -- 3.6 Chapter Summary -- References -- 4 Development of pH- and Redox-activated Self-healing Coating -- 4.1 Introduction -- 4.2 pH Responsive Self-healing Coating Based on the Synergistic Effect of Two Corrosion Inhibitors -- 4.3 pH Responsive Self-healing Coating Based on rGO@MS-P-BTA -- 4.4 Redox and Saline Responsive Self-healing Coating Based on PANI/BTA Nanocapsules -- 4.5 Chapter Summary -- References -- 5 Development of Ion Exchange Activated Self-healing Coating -- 5.1 Introduction -- 5.2 Ion Exchange Activated Self-healing Coating Using GO-LDH Fillers -- 5.3 Chapter Summary -- References -- 6 Development of pH-responsive and Metal Ion-responsive Self-reporting Coating -- 6.1 Introduction -- 6.2 pH-responsive Self-reporting Coatings Based on PhPh Indicator -- 6.3 Metal Ion-responsive Self-reporting Coatings Based on CDs -- 6.4 Metal Ion-responsive Self-reporting Coatings Based on UF/Phen Microcapsules -- 6.5 Chapter Summary -- References -- 7 Development of Mechanically Responsive Self-reporting Coating -- 7.1 Introduction -- 7.2 Mechanically Responsive Self-reporting Coating Based on DCF -- 7.3 Chapter Summary -- References -- 8 Development of Aging-Resistant Coating with Self-healing and Self-reporting Properties -- 8.1 Introduction -- 8.2 Aging-Resistant, Self-healing, and Self-reporting Smart Coatings Based on TA Additives -- 8.3 Aging-Resistant Anticorrosion Coatings Based on TP Additives -- 8.4 Chapter Summary -- References -- 9 Development of Superhydrophobic Coating with Good Mechanical Durability and Self-healing Effect -- 9.1 Introduction -- 9.2 Preparation and Evaluation of Modified Nano SiO 2 /Epoxy Resin Superhydrophobic Coating -- 9.3 Preparation and Evaluation of CNTs/Epoxy Resin Superhydrophobic Coating -- 9.4 Shape Memory Self-healing Superhydrophobic Coating Based on SiO 2 -CNT Hybrids -- 9.5 Superhydrophobic Self-healing Coating Based on CNTs/LDH Nanocontainers Loaded with Corrosion Inhibitors -- 9.6 Chapter Summary -- References -- 10 Investigation of the Self-healing Performance of Coatings Using Atmospheric Corrosion Monitor Technique -- 10.1 Introduction -- 10.2 Characterization Methods for Corrosion Protection Coatings -- 10.3 Study of the Self-healing Behavior of Coatings Using ACM Technique -- 10.4 Chapter Summary -- References -- 11 Future Development Direction of Smart Anticorrosive Coatings -- 11.1 Introduction -- 11.2 Smart Self-healing Coatings -- 11.3 Smart Self-reporting Coatings -- 11.4 Superhydrophobic Coatings -- 11.5 Application of Atmospheric Corrosion Monitor Technology in Smart Coating Design -- Index.