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Theory and applications of green corrosion inhibitors / edited by Inamuddin [and three others].
- Format:
- Book
- Author/Creator:
- Inamuddin
- 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 &
- 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
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