Tribocorrosion : fundamentals, methods, and materials / edited by Rahul Ramachandran, Pradeep Menezes, Arpith Siddaiah.

Format:

Book

Contributor:

Ramachandran, Rahul, editor.

Menezes, Pradeep, editor.

Siddaiah, Arpith, editor.

Language:

English

Subjects (All):

Tribo-corrosion.

Physical Description:

1 online resource (234 pages)

Edition:

1st ed.

Place of Publication:

Amsterdam, Netherlands : Academic Press, [2021]

Summary:

Tribocorrosion: Fundamentals, Methods, and Materials provides a balanced coverage of recent advancements in both experimental and computational areas of tribocorrosion, covering the basic concepts of tribology and electrochemistry, as well as testing set-ups, protocols, electrochemical methods, and more.

Contents:

Front Cover

Tribocorrosion

Copyright Page

Contents

List of contributors

1 Introduction to tribocorrosion

1.1 Background

1.1.1 Tribocorrosion

1.1.2 Wear-accelerated corrosion

1.1.3 Corrosion-accelerated wear

1.1.4 Understanding tribocorrosion measurement

1.2 Measurement techniques

1.2.1 Tribocorrosion at open circuit potential

1.2.2 Tribocorrosion at constant potential

1.2.3 Tribocorrosion using potentiodynamic polarization

1.2.4 Tribocorrosion at zero resistance ammeter

1.3 Summary

Acknowledgment and funding information

References

2 Experimental investigation of tribocorrosion

2.1 Introduction

2.2 Tribocorrosion: evaluation techniques, applications, and limitations

2.2.1 Anodic/cathodic potential tribocorrosion test

2.2.2 Potentiodynamic polarization test

2.2.3 Potentiostatic polarization test

2.2.4 Combination of potentiodynamic and potentiostatic polarization techniques

2.2.5 Open circuit potential tribocorrosion test

2.2.5.1 Open circuit potential monitoring

2.2.5.2 Electrochemical impedance spectroscopy

2.2.5.3 Combination of open circuit potential monitoring and impedance measurements

2.3 Influential factors of tribocorrosion

2.3.1 Materials properties

2.3.2 Microstructure

2.3.3 Solution/environment

2.3.4 Electrochemical parameters

2.3.5 Mechanical aspects

2.4 Challenges in the tribocorrosion measurement

2.5 Tribocorrosion behavior of aluminum-based in situ composite: a case study

2.5.1 Influence of speed of slurry rotation

2.5.2 Influence of impinging particle size

2.5.3 Influence of slurry concentration

2.5.4 Influence of test duration

2.5.5 Slurry erosive wear mechanism in in situ composites

2.6 Conclusions

3 Electrochemical methods in tribocorrosion

3.1 Introduction.

3.2 Need of tribocorrosion study

3.3 Tribocorrosion behavior of coatings

3.4 Applications of tribology and tribocorrosion studies

3.5 Passivation in metals

3.6 Electrochemical testing for corrosion studies

3.6.1 Open circuit potential measurements

3.6.2 Electrochemical impedance spectroscopy

3.6.3 Linear polarization resistance measurements

3.6.4 Potentiodynamic and potentiostatic polarization

3.7 Triboelectrochemical experiments

3.8 Effect of applied potential on friction coefficient

3.9 Synergism of wear and corrosion

3.9.1 Impedance behavior of a tribocorrosion system

3.10 Potentiostat for electrochemical measurements

3.10.1 Potentiodynamic polarization measurements

3.10.2 Determination of corrosion potential (Ecorr)

3.10.3 Determination of corrosion current density (icorr)

3.11 Examples of triboelectrochemical studies

3.12 Limitations of electrochemical techniques in tribocorrosion studies

3.13 Summary

4 Tribocorrosion mechanisms in sliding contacts

4.1 Introduction

4.2 Tribocorrosion in cast-wrought steels

4.3 Tribocorrosion and passivation

4.4 Tribocorrosion of powder metallurgy parts

4.5 Tribocorrosion of laser-processed parts

4.6 Conclusion and future scope

Acknowledgements

5 Tribocorrosion aspects of implant coatings: Hip replacements

5.1 Introduction

5.1.1 Biomedical implants

5.1.2 Tribocorrosion aspects

5.1.3 Tribocorrosion in hip implant

5.1.3.1 Sliding-corrosion

5.1.3.2 Fretting corrosion in hip implant

5.1.4 Wear-corrosion synergism: Key aspects of the tribocorrosion

5.1.5 Research in tribocorrosion of implants

5.2 Surface coatings/modifications on the implant

5.2.1 Types of the surface modifications

5.2.2 Types of the coatings

5.2.2.1 Hard-ceramic coating

5.2.2.2 Carbonaceous coatings.

5.2.3 The risk associated with coatings for the implants

5.3 Surface coatings/modifications on the implant surface to improve tribocorrosion resistance

5.3.1 Deposited hard-ceramic coatings

5.3.2 Surface modification by chemical reactions

5.3.2.1 Oxidation

5.3.2.2 Carburization

5.3.3 Carbonaceous coatings

5.3.3.1 Naturally formed tribolayer

5.3.4 Carbide-derived carbon

5.4 Current setback of the coatings applied on biomedical implants

5.4.1 Delamination risks

5.4.2 Accelerated tribocorrosion mechanisms

5.4.3 Evaluation of surviving life of coatings in operation

5.4.4 Toxicity concerns

5.5 Summary

Acknowledgments

6 Tribocorrosion of hard coatings and thin films

6.1 Introduction

6.2 Titanium-based nitride coatings

6.3 Tribocorrosion of titanium-based nitride coatings

6.4 Chromium-based nitride coatings

6.5 Tribocorrosion of chromium-based nitride coatings

6.6 Tribocorrosion of other nitride coatings

6.7 Diamond-like carbon coatings

6.8 Tribocorrosion of DLC coatings

6.9 Tribocorrosion of transition metal, transition metal carbide, and transition metal boride coatings

6.10 Tribocorrosion of nanostructured multilayer coatings

6.11 Nanostructured coatings and thin films

6.12 Design guidelines and outlook

7 Importance of in vitro assessment of total hip arthroplasty using hip simulator and preliminary results

7.1 Introduction

7.2 Evolution of bearing combination in total hip replacement

7.2.1 FDA-approved bearing surfaces

7.2.1.1 Metal-on-polyethylene

7.2.1.2 Ceramic-on-polyethylene

7.2.1.3 Metal-on-metal

7.2.1.4 Ceramic-on-ceramic

7.3 Total hip replacement statistics

7.3.1 The revision burden

7.4 Preclinical evaluation of the bearing material

7.4.1 Wear and tribocorrosion testing devices.

7.4.2 Lubricants for in vitro testing

7.4.3 The need of a hip joint wear simulator

7.5 Hip joint wear simulator

7.5.1 Simulator developed worldwide

7.5.2 International guidelines

7.6 Results and discussion

7.7 Future of hip simulator studies

7.8 Conclusion

Acknowledgment

8 Computational methods in tribocorrosion

8.1 Introduction

8.2 Mechanistic models of tribocorrosion

8.2.1 Mechanistic models for sliding contact

8.2.1.1 Synergy of mechanical and electrochemical wear

8.2.1.2 Wear-accelerated corrosion models

8.2.1.3 Film repassivation models

8.2.1.4 Models of galvanic effect in tribocorrosion

8.2.2 Fretting tribocorrosion models

8.2.3 Lubrication model with tribocorrosion

8.3 Deterministic tribocorrosion models

8.3.1 Microscale models

8.4 Summary and future directions

Index

Back Cover.

Notes:

Description based on print version record.

Description based on publisher supplied metadata and other sources.

ISBN:

9780128189177

0128189177

9780128189160

0128189169

OCLC:

1249473648