Atmospheric Corrosion

ATMOSPHERIC CORROSION

Presents a comprehensive look at atmospheric corrosion, combining expertise in corrosion science and atmospheric chemistry

Atmospheric corrosion has been a subject of engineering study, largely empirical, for nearly a century. Scientists came to the field rather later on and had considerable difficulty bringing their arsenal of tools to bear on the problem. Atmospheric corrosion was traditionally studied by specialists in corrosion having little knowledge of atmospheric chemistry, history, or prospects.

Atmospheric Corrosion provides a combined approach bringing together experimental corrosion and atmospheric chemistry. The second edition expands on this approach by including environmental aspects of corrosion, atmospheric corrosion modeling, and international corrosion exposure programs. The combination of specialties provides a more comprehensive coverage of the topic. These scientific insights into the corrosion process and its amelioration are the focus of this book.

Key topics include the following:

• Basic principles of atmospheric corrosion chemistry

• Corrosion mechanisms in controlled and uncontrolled environments

• Degradation of materials in architectural, transport, and structural applications; electronic devices; and cultural artifacts

• Protection of existing materials and choosing new ones that resist corrosion

• Prediction of how and where atmospheric corrosion may evolve in the future

Complete with appendices discussing experimental techniques, computer models, and the degradation of specific metals, Atmospheric Corrosion, Second Edition continues to be an invaluable resource for corrosion scientists, corrosion engineers, conservators, environmental scientists, and anyone interested in the theory and application of this evolving field. The book concerns primarily the atmospheric corrosion of metals and is written at a level suitable for advanced undergraduates or beginning graduate students in any of the physical or engineering sciences.

Auteur

Christofer Leygraf is Professor Emeritus at KTH Royal Institute of Technology, Division of Surface and Corrosion Science, Stockholm, Sweden. Inger Odnevall Wallinder is Professor at KTH Royal Institute of Technology, Division of Surface and Corrosion Science, Stockholm, Sweden. Johan Tidblad is Manager for the Section Corrosion Protection and Surface Technology at Swerea KIMAB, Stockholm, Sweden. Thomas Graedel is Professor Emeritus at Yale School of Forestry and Environmental Studies, New Haven, Connecticut, USA.

Résumé
ATMOSPHERIC CORROSION Presents a comprehensive look at atmospheric corrosion, combining expertise in corrosion science and atmospheric chemistry Atmospheric corrosion has been a subject of engineering study, largely empirical, for nearly a century. Scientists came to the field rather later on and had considerable difficulty bringing their arsenal of tools to bear on the problem. Atmospheric corrosion was traditionally studied by specialists in corrosion having little knowledge of atmospheric chemistry, history, or prospects. Atmospheric Corrosion provides a combined approach bringing together experimental corrosion and atmospheric chemistry. The second edition expands on this approach by including environmental aspects of corrosion, atmospheric corrosion modeling, and international corrosion exposure programs. The combination of specialties provides a more comprehensive coverage of the topic. These scientific insights into the corrosion process and its amelioration are the focus of this book. Key topics include the following:

• Basic principles of atmospheric corrosion chemistry
• Corrosion mechanisms in controlled and uncontrolled environments
• Degradation of materials in architectural, transport, and structural applications; electronic devices; and cultural artifacts
• Protection of existing materials and choosing new ones that resist corrosion
• Prediction of how and where atmospheric corrosion may evolve in the future Complete with appendices discussing experimental techniques, computer models, and the degradation of specific metals, Atmospheric Corrosion, Second Edition continues to be an invaluable resource for corrosion scientists, corrosion engineers, conservators, environmental scientists, and anyone interested in the theory and application of this evolving field. The book concerns primarily the atmospheric corrosion of metals and is written at a level suitable for advanced undergraduates or beginning graduate students in any of the physical or engineering sciences.

Contenu
Preface xv

1 The Many Faces of Atmospheric Corrosion 1

1.1 Dr. Vernon's Legacy 1

1.2 Concepts and Consequences 2

1.3 The Evolution of a Field 3

1.4 Controlled Laboratory Environments 4

1.5 Uncontrolled Field Environments 5

1.6 New Approaches to Atmospheric Corrosion Studies 6

1.7 An Overview of this Book 6

2 A Conceptual Picture of Atmospheric Corrosion 7

2.1 Introduction 7

2.2 Initial Stages of Atmospheric Corrosion 7

2.3 Intermediate Stages of Atmospheric Corrosion 11

2.4 Final Stages of Atmospheric Corrosion 17

Further Reading 20

3 A Multiregime Perspective on Atmospheric Corrosion Chemistry 22

3.1 Introduction to Moist-Layer Chemistry 22

3.2 The Gaseous Regime 24

3.3 The Interface Regime 25

3.4 The Liquid Regime 27

3.5 The Deposition Regime 28

3.6 The Electrodic Regime 30

3.7 The Solid Regime 31

3.8 The Multiregime Perspective 32

Further Reading 32

4 Atmospheric Gases and their Involvement in Corrosion 34

4.1 Chemical Species of Interest 34

4.2 Atmospheric Corrosive Gases 35

4.3 Historic Trends in Atmospheric Corrosive Gas Concentrations 40

4.4 Predicted Future Emissions of Corrosive Species 43

Further Reading 45

5 Atmospheric Particles and their Involvement in Corrosion 46

5.1 Introduction 46

5.2 Chemical Species of Interest 49

5.3 Sources of Atmospheric Aerosol Particles 50

5.4 Aerosol Particle Physics and Chemistry 51

5.5 Implications of Aerosol Particles for Atmospheric Corrosion 55

Further Reading 57

6 Corrosion in Laboratory Exposures 59

6.1 The Need for Well-Defined Laboratory Experiments 59

6.2 Considerations for Specific Metals 59

6.3 Design Considerations 60

6.4 Examples of Important Laboratory Exposures 65

6.5 Can Corrosion Processes in the Field be Reasonably Simulated by Laboratory Experiments? 67

6.6 Computational Model Studies of SO2-Induced Atmospheric Corrosion of Copper 70

6.7 Summary 76

Further Reading 77

7 Corrosion in Indoor Exposures 79

7.1 General Characteristics of Indoor Environments 79

7.2 The Interplay Between Pollutants and Corrosion Rates 85

7.3 Corrosion Rates 88

7.4 Indoor Corrosion Products 93

7.5 Indoor Environmental Classification 94

7.6 An Example of Indoor Corrosion: Metal Artifacts 95

7.7 Summary 98

Further Reading 99

8 Corrosion in Outdoor Exposures 100

8.1 The Effect of Exposure Conditions 100

8.2 Design Considerations 101

8.3 Influence of Exposure Parameters 103

8.4 DoseResponse Functions 114

8.5 Summary 118

Further Reading 118

9 Advanced Stages of Corrosion 121

9.1 Introduction 121

9.2 Evolution of Corrosion Products on Zinc 122

9.4 Evolution of Corrosion Products on Carbon Steel 140

9.5 Evolution of Corrosion Products on Aluminum 144

9.6 Summary 146

Further Reading 148

10 Environmental Dispersion of Metals From Corroded Outdoor Constructions 151

10.1 Introduction 151

10.2 Metal Dispersion (Runoff): Atmospheric Corrosion 152

10.3 Time-Dependent Aspects and Importance of Rain and Environmental Conditions 154

10.4 Influence of Construction Geometry on the Metal Runoff and Runoff Rate Predictions 159

10.5 Environmental Fate and Speciation:…