Theory and applications of green corrosion inhibitors / edited by Inamuddin [and three others].

Format:

Book

Author/Creator:

Inamuddin

Contributor:

Inamuddin, editor.

Series:

Materials research foundations ; Volume 86.

Materials research foundations ; Volume 86

Language:

English

Subjects (All):

Corrosion resistant materials.

Physical Description:

1 online resource (242 pages).

Edition:

1st ed.

Place of Publication:

Millersville, PA : Materials Research Forum LLC, [2021]

Summary:

The book presents theoretical insights, characterization tools and mechanisms of green corrosion inhibitors.

Contents:

Intro

front-matter

Table of Contents

Preface

1

Theoretical Insights in Green Corrosion Inhibitors

1. Introduction

2. Theoretical methods used in green corrosion inhibitors

2.1 Quantum chemistry methods

2.2 Quantitative structure-activity relationships

2.3 Molecular dynamics simulation

3. The progress of theoretical study in green corrosion inhibitors

3.1 The behavior of green corrosion inhibitor studied by combination of quantum chemistry and QSAR

3.1.1 Carbon steel inhibitors

3.1.2 Copper inhibitors

3.2 The performance of green corrosion inhibitor studied by combination of molecular simulation and quantum chemistry

3.2.1 Carbon steel inhibitor

3.2.2 Aluminum inhibitors

3.2.3 Copper inhibitors

3.3 The behavior of green corrosion inhibitor studied by combination of molecular simulation, quantum chemistry and QSAR

3.3.1 Carbon steel inhibitors

3.3.2 Copper inhibitors

Conclusions

Acknowledgments

References

2

Effect of Natural Sources on the Corrosion Inhibition

2. Green corrosion inhibitors

2.1 Protection of iron based surfaces via green corrosion inhibitors

2.1.1 Protection of iron surfaces via green corrosion inhibitors

2.1.2 Protection of mild steel surfaces via green corrosion inhibitors

2.1.3 Protection of steel surfaces via green corrosion inhibitors

2.1.4 Protection of carbon steel surfaces via green corrosion inhibitors

2.1.5 Protection of steel rebar surfaces via green corrosion inhibitors

2.2 Protection of aluminum surfaces via green corrosion inhibitors

2.3 Protection of copper surfaces via green corrosion inhibitors

2.4 Protection of tin surfaces via green corrosion inhibitors

2.5 Green corrosion inhibitors resources

3. Anti-corrosion mechanism (for natural inhibitors).

3.1 Anodic, cathodic and mixed type inhibition

4. Corrosion inhibitors testing

5. Economic and industrial opportunities

3

Green Inhibitors for Biocorrosion and Prevention

1.1 The portability of the metal to the corrosion

1.2 The factors affecting the speed of corrosion

1.3 Types of corrosions

1.3.1 Pure chemical corrosion

1.3.2 Electrochemical corrosion

1.3.3 Homogeneous (general) corrosion

1.3.4 Local corrosion

1.3.5 Stress - corrosion cracking

1.3.6 Galvanic corrosion

1.3.7 Erosion corrosion (EC)

1.3.8 Crevice corrosion

1.3.9 Pitting corrosion (PC)

1.3.10 Exfoliation corrosion

1.3.11 Selective leaching

1.3.12 Nonmetallic corrosion

1.3 Corrosion of cement

1.5 Corrosion of organic materials

1.6 Environment factors

1.6.1 Effect of oxygen and oxidants

1.6.2 Effect of pH

1.6.2 Effect of anions and cations

1.7 Anti-corrosion methods

1.7.1 The green impediments for corrosion

1.7.2 Determination of green corrosion inhibitors based on ionic fluids

1.7.3 Corrosion suppressions from the biological waste

Conclusion

4

Electrochemical Studies of Green Corrosion Inhibitors

2. Corrosion inhibitors

2.1 Green corrosion inhibitors

2.1.1 Natural products

2.1.2 Amino acids

2.1.3 Rare earth metal compounds

2.1.4 Recently used green inhibitors

3. Characterization techniques

3.1 Polarization methods

3.1.1 Linear polarization resistance method

3.1.2 Potentiodynamic-galvanodynamic polarization

3.1.3 Cyclic potentiodynamic polarization

3.1.4 Cyclic galvano-staircase polarization

3.1.5 Conversion of Icorr (from polarization methods) to corrosion rates

3.1.6 Limitations associated with polarization methods

3.2 Electrochemical impedance spectroscopy (EIS).

3.2.1 Interpretation of results (Nyquist &amp

Bode plots)

3.2.2 Equivalent circuits

3.3 Electrochemical Noise (EN) measurements

3.4 Electrochemical Quartz Crystal Microbalance (EQCM)

Concluding remark

5

Green Corrosion Inhibitors for Technological Applications

3. Technological applications of green corrosion inhibitors

3.1 Oil and gas sector

3.2 Reinforced concrete

3.3 Acid pickling industry

3.4 Coatings

3.5 Aircraft industry

3.6 Water industry

Acknowledgment

6

Pyrazine Derivatives as Green Corrosion Inhibitors

2. Pyrazine and its derivative as prominent corrosion inhibitor for metals and alloys in corrosive media

3. Adsorption mechanism

Further aspects

Abbreviations

Acknowledgement

7

Biological Corrosion Inhibitors for Concrete

2. Biological Corrosion Inhibitors

2.1 Microbial

2.1.1 Bacterial

2.1.1.1 Ureolytic

2.1.1.2 Non-ureolytic

2.1.2 Nitrate reducing bacteria

2.1.3 Biomolecules

2.1.4 Deoxyribonucleic acid (DNA)

2.1.5 Mussel adhesive proteins

2.1.6 Fungus

2.2 Botanical

2.2.1 Extract of tree/plant leaves

2.2.2 Bark extract of trees/plants

2.2.3 Seeds or grains

2.2.4 Plant roots extracts

2.2.5 Plants mucilage

2.2.6 Algae

3. Comparison

8

Green Corrosion Inhibitor for Electronics

2. Causes and factors for corrosion in electronics

2.1 Contaminant gases affect the manufacturing areas

2.2 Other problems faced in manufacturing process

2.3 Effects of ammonia

2.4 Effects of ozone, boron and other volatile organic compounds

2.5 Airborne contamination in various sector

2.5.1 Telecom industry.

2.5.2 Distributed control system (DCS)

2.5.3 Data centers

3. Metals or specific alloys component for electronics

4. Electronic component susceptibility towards corrosion and failure analysis

4.1 Printed circuit board

4.2 Contact and connector

4.2.1 Pore corrosion in electrical contacts

4.2.2 Fretting corrosion of electronic connectors

4.3 Integrated circuits

4.4 Solder corrosion: the corrosive effect of soldering flux

4.5 Hermetic packages

5. Reliability and cleanliness

6. Electronics corrosion protection

7. Vapor phase corrosion inhibitor (VPCI) technology

8. Vapor pressure measurement by various methods

8.1 Regnault dynamic method

8.2 Boiling point determination method

8.3 Knudsen effusion method

8.4 Microbalance method

8.5 Torsion effusion method

9. Effect of temperature on the vapor pressure

10. Effect of pH

11. Types of vapor phase corrosion inhibitors (VPCI)

12. Analysis of corrosion by different method

12.1 Vapor pressure determination

12.2 Weight loss method

12.3 Esckhe method

12.4 Salt spray method

13. Advantages of VPCI

back-matter

Keyword Index

About the Editors.

Notes:

Description based on print version record.

Description based on publisher supplied metadata and other sources.

ISBN:

1-64490-105-6

OCLC:

1202526048