E-Book, Englisch, 476 Seiten
Dey / Mukhopadhyay Nanoindentation of Brittle Solids
1. Auflage 2014
ISBN: 978-1-4665-9691-7
Verlag: Taylor & Francis
Format: PDF
Kopierschutz: Adobe DRM (»Systemvoraussetzungen)
E-Book, Englisch, 476 Seiten
ISBN: 978-1-4665-9691-7
Verlag: Taylor & Francis
Format: PDF
Kopierschutz: Adobe DRM (»Systemvoraussetzungen)
Understanding the Basics of Nanoindentation and Why It Is Important
Contact damage induced brittle fracture is a common problem in the field of brittle solids. In the case of both glass and ceramics—and as it relates to both natural and artificial bio-materials—it has triggered the need for improved fabrication technology and new product development in the industry.
The Nanoindentation Technique Is Especially Dedicated to Brittle Materials
Nanoindentation of Brittle Solids highlights the science and technology of nanoindentation related to brittle materials, and considers the applicability of the nanoindentation technique. This book provides a thorough understanding of basic contact induced deformation mechanisms, damage initiation, and growth mechanisms. Starting from the basics of contact mechanics and nanoindentation, it considers contact mechanics, addresses contact issues in brittle solids, and explores the concepts of hardness and elastic modulus of a material. It examines a variety of brittle solids and deciphers the physics of deformation and fracture at scale lengths compatible with the microstructural unit block.
- Discusses nanoindentation data analysis methods and various nanoindentation techniques
- Includes nanoindentation results from the authors’ recent research on natural biomaterials like tooth, bone, and fish scale materials
- Considers the nanoindentation response if contact is made too quickly in glass
- Explores energy issues related to the nanoindentation of glass
- Describes the nanoindentation response of a coarse grain alumina
- Examines nanoindentation on microplasma sprayed hydroxyapatite coatings
Nanoindentation of Brittle Solids provides a brief history of indentation, and explores the science and technology of nanoindentation related to brittle materials. It also offers an in-depth discussion of indentation size effect; the evolution of shear induced deformation during indentation and scratches, and includes a collection of related research works.
Zielgruppe
Mechanical and ceramic engineers; material scientists; nanotechnologists; biomedical engineers; physicists; and industry professionals.
Autoren/Hrsg.
Fachgebiete
Weitere Infos & Material
Section 1 Contact Mechanics
Contact Issues in Brittle Solids
Payel Bandyopadhyay, Debkalpa Goswami, Nilormi Biswas, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Elasticity and Plasticity
Stresses
Conclusions
References
Mechanics of Elastic and Elastoplastic Contacts
Manjima Bhattacharya, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
The Different Models
Conclusions
References
Section 2 Journey Towards Nanoindentation
Brief History of Indentation
Nilormi Biswas, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
How Did It All Happen?
And Then There Was a
Modern Developments: Nineteenth-Century Scenario
Comparison of Techniques
Major Developments beyond 1910
Beyond the Vickers and Knoop Indenters
Conclusions
References
Hardness and Elastic Modulus
Nilormi Biswas, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Conceptual Issues
Beyond the Hertzian Era: Modern Contact Mechanics
The Experimental Issues
Elastic Modulus
Techniques to Determine Elastic Modulus
Conclusions
References
Nanoindentation: Why at All and Where?
Arjun Dey, Payel Bandyopadhyay, Nilormi Biswas, Manjima Bhattacharya, Riya Chakraborty, I Neelakanta Reddy, and Anoop Kumar Mukhopadhyay
Introduction
In Situ Nanoindentation
Conclusions
References
Nanoindentation Data Analysis Methods
Manjima Bhattacharya, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Modeling of the Nanoindentation Process
Conclusions
References
Nanoindentation Techniques
Manjima Bhattacharya, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Conclusions
References
Instrumental Details
Payel Bandyopadhyay, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Nanoindenters: Tip Details and Tip Geometries
Conclusions
References
Materials and Measurement Issues
Arjun Dey, Riya Chakraborty, Payel Bandyopadhyay, Nilormi Biswas, Manjima Bhattacharya, Saikat Acharya, and Anoop Kumar Mukhopadhyay
Introduction
Materials
Nanoindentation Studies
The Scratch Tests
Microstructural Characterizations
Conclusions
References
Section 3 Static Contact Behavior of Glass
What If the Contact is Too Quick in Glass?
Riya Chakraborty, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Effect of Loading Rate on Nanohardness
Damage Evolution Mechanism
Conclusions
References
Enhancement in Nanohardness of Glass: Possible?
Riya Chakraborty, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Nanomechanical Behavior
Conclusions
References
Energy Issues in Nanoindentation
Riya Chakraborty, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Energy Models
Energy Calculation
Conclusions
References
Section 4 Dynamic Contact Behavior of Glass
Dynamic Contact Damage in Glass
Payel Bandyopadhyay, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Damage Due to Dynamic Contact
Conclusions
References
Does the Speed of Dynamic Contact Matter?
Payel Bandyopadhyay, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Effect of Speed of Dynamic Contacts and Damage Evolution
Conclusions
References
Nanoindentation Inside the Scratch: What Happens?
Payel Bandyopadhyay, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Nanoindentation Inside a Scratch Groove
The Model of Microcracked Solids
Conclusions
References
Section 5 Static Contact Behavior of Ceramics
Nanomechanical Properties of Ceramics
Riya Chakraborty, Manjima Bhattacharya, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Nanoindentation Study
Indentation Size Effect (ISE) in Alumina
Conclusions
References
Does the Contact Rate Matter for Ceramics?
Manjima Bhattacharya, Riya Chakraborty, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Effect of Loading Rate and "Multiple Micro Pop-in" and
"Multiple Micro Pop-out"
Conclusions
References
Nanoscale Contact in Ceramics
Manjima Bhattacharya, Riya Chakraborty, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Evolutions of Pop-ins
Conclusions
References
Section 6 Static Behavior of Shock-Deformed Ceramics
Shock Deformation of Ceramics
Riya Chakraborty, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Nanoindentation Study
Occurrence of Pop-ins
Defects in Shock-Recovered Alumina
Conclusions
References
Nanohardness of Alumina
Riya Chakraborty, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Indentation Size Effect of Shocked Alumina
Deformation of Shocked Alumina
Micro Pop-ins of Shocked Alumina
Conclusions
References
Interaction of Defects with Nanoindents in Shocked Ceramics
Riya Chakraborty, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Indentation Size Effect of Alumina Shocked at High Shock
Pressure
Deformation Due to Shock at High Pressure
Conclusions
References
Effect of Shock Pressure on ISE: A Comparative Study
Riya Chakraborty, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Comparison of ISE in Alumina Shocked at 6.5 and 12 GPa
Shear Stress and Micro Pop-ins
Comparison of Deformations in Alumina Shocked at 6.5 and 12 GPa
Conclusions
References
Section 7 Nanoindentation Behavior of Ceramic-Based Composites
Nano/Micromechanical Properties of C/C and C/C-SiC
Composites
Soumya Sarkar, Arjun Dey, Probal Kumar Das, Anil Kumar, and Anoop Kumar Mukhopadhyay
Introduction
Nanoindentation Behavior
Energy Calculation
Conclusions
References
Nanoindentation on Multilayered Ceramic Matrix Composites
Sadanand Sarapure, Arnab Sinha, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Nanomechanical Behavior
Conclusions
References
Nanoindentation of Hydroxyapatite-Based Biocomposites
Shekhar Nath, Arjun Dey, Prafulla K Mallik, Bikramjit Basu, and Anoop Kumar Mukhopadhyay
Introduction
HAp-Calcium Titanate Composite
HAp-Mullite Composite
Conclusions
References
Section 8 Nanoindentation Behavior of Functional Ceramics
Nanoindentation of Silicon
Arjun Dey and Anoop Kumar Mukhopadhyay
Introduction
Nanoindentation Response
Conclusions
References
Nanomechanical Behavior of ZTA
Sadanand Sarapure, Arnab Sinha, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Nanomechanical Behavior
Conclusions
References
Nanoindentation Behavior of Actuator Ceramics
Sujit Kumar Bandyopadhyay, A K Himanshu, Pintu Sen, Tripurari Prasad Sinha, Riya Chakraborty, Arjun Dey, Payel Bandyopadhyay, and Anoop Kumar Mukhopadhyay
Introduction
Nanoindentation Behavior
Polarization Behavior
Conclusions
References
Nanoindentation of Magnetoelectric Multiferroic Material
Pintu Sen, Arjun Dey, Anoop Kumar Mukhopadhyay, Sujit Kumar Bandyopadhyay, and A K Himanshu
Introduction
Nanoindentation Response
Conclusions
References
Nanoindentation Behavior of Anode-Supported Solid Oxide Fuel Cell
Rajendra Nath Basu, Tapobrata Dey, Prakash C Ghosh, Manaswita Bose, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Nanomechanical Behavior
Conclusions
References
Nanoindentation Behavior of High-Temperature Glass–Ceramic Sealants for Anode-Supported Solid Oxide Fuel Cell
Rajendra Nath Basu, Saswati Ghosh, A Das Sharma, P Kundu, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Preparation of the Sealant Glass–Ceramic
Nanomechanical Properties
Conclusions
References
Section 9 Static Contact Behavior of Ceramic Coatings
Nanoindentation on HAp Coating
Arjun Dey, Payel Bandyopadhyay, Nil Ratan Bandyopadhyay, and Anoop Kumar Mukhopadhyay
Introduction
Influence of Load on Nanohardness and Young’s Modulus
Conclusions
References
Weibull Modulus of Ceramic Coating
Arjun Dey and Anoop Kumar Mukhopadhyay
Introduction
Data Reliability Issues in MIPS–HAp Coatings
Conclusions
References
Anisotropy in Nanohardness of Ceramic Coating
Arjun Dey and Anoop Kumar Mukhopadhyay
Introduction
Nanohardness Behavior: Anisotropy
Conclusions
References
Fracture Toughness of Ceramic Coating Measured by Nanoindentation
Arjun Dey and Anoop Kumar Mukhopadhyay
Introduction
Fracture Toughness Behavior
Conclusions
References
Effect of SBF Environment on Nanomechanical and Tribological Properties of Bioceramic Coating
Arjun Dey and Anoop Kumar Mukhopadhyay
Introduction
Nano-/Micro-mechanical Behavior
Tribological Study
Conclusions
References
Nanomechanical Behavior of Ceramic Coatings Developed by Micro Arc Oxidation
Arjun Dey, R Uma Rani, Hari Krishna Thota, A Rajendra, Anand Kumar Sharma, Payel Bandyopadhyay, and Anoop Kumar Mukhopadhyay
Introduction
Nanoindentation Study and Reliability Issue
Conclusions
References
Section 10 Static Contact Behavior of Ceramic Thin Films
Nanoindentation Behavior of Soft Ceramic Thin Films: Mg(OH)2
Pradip Sekhar Das, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Nanoindentation Study
Energy Calculation
Conclusions
References
Nanoindentation Study on Hard Ceramic Thin Films: TiN
Arjun Dey and Anoop Kumar Mukhopadhyay
Introduction
Nanoindentation Study
DepthDependent Nanomechanical Behavior
Conclusions
References
Nanoindentation Study on Sputtered Alumina Films for Spacecraft Application
I Neelakanta Reddy, N Sridhara, V Sasidhara Rao, Anju M Pillai, Anand Kumar Sharma, V R Reddy, Anoop Kumar Mukhopadhyay, and Arjun Dey
Introduction
Optical Behavior
Nanomechanical Behavior
Conclusions
References
Nanomechanical Behavior of Metal-Doped DLC Thin Films
Arjun Dey, Rajib Paul, A K Pal, and Anoop Kumar Mukhopadhyay
Introduction
Nanoindentation Study
Nanotribological Study
Adhesion Mechanisms
Conclusions
References
Section 11 Nanoindentation Behavior on Ceramic-Based Natural Hybrid Nanocomposites
Orientational Effect in Nanohardness of Tooth Enamel
Nilormi Biswas, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Nanomechanical Behavior and Energy Issues
Micro Pop-in Events
Conclusions
References
Slow or Fast Contact: Does it Matter for Enamel?
Nilormi Biswas, Arjun Dey, and Anoop Kumar Mukhopadhyay
Introduction
Loading Rate Effect
Evolution of Micro Pop-in Events
Loading Rate versus Micro/Nanostructure
Conclusions
References
Anisotropy of Modulus in Cortical Bone
Arjun Dey, Himel Chakraborty, and Anoop Kumar Mukhopadhyay
Introduction
Microstructure
Nanomechanical Behavior and Anisotropy
Conclusions
References
Nanoindentation of Fish Scale
Arjun Dey, Himel Chakraborty, and Anoop Kumar Mukhopadhyay
Introduction
Microstructure
Nanomechanical Behavior
Conclusions
References
Section 12 Some Unresolved Issues in Nanoindentation
Indentation Size Effect (ISE) and Reverse Indentation Size Effect (RISE) in Nanoindentation
Arjun Dey, Devashish Kaushik, Nilormi Biswas, Saikat Acharya, Riya Chakraborty, and Anoop Kumar Mukhopadhyay
Introduction
ISE in HAp Coating
ISE and RISE in AlN-SiC Composites
ISE in Dentin
ISE in SLS Glass
Conclusions
References
Pop-in Issues in Nanoindentation
Riya Chakraborty, Arjun Dey, Manjima Bhattacharya, Nilormi Biswas, Jyoti Kumar Sharma, Devashish Kaushik, Payel Bandyopadhyay, Saikat Acharya, and Anoop Kumar Mukhopadhyay
Introduction
What is Known about Pop-ins?
Pop-ins in Nanoindentation of Brittle Solids
Conclusions
References
Effect of Loading Rate on Nanoindentation Response of Brittle Solids
Riya Chakraborty, Arjun Dey, Nilormi Biswas, Manjima Bhattacharya, Payel Bandyopadhyay, Jyoti Kumar Sharma, Devashish Kaushik, Saikat Acharya, and Anoop Kumar Mukhopadhyay
Introduction
LoadingRate Effects in Brittle Solids: SLS Glass and Alumina
Conclusions
References
Measurement of Residual Stress by Nanoindentation Technique
Arjun Dey and Anoop Kumar Mukhopadhyay
Introduction
Measurement of Residual Stress by Nanoindentation: Concept
Evaluation of Residual Stress by Nanoindentation of HAp
Coating
Conclusions
References
Reliability Issues in Nanoindentation Measurements
Arjun Dey and Anoop Kumar Mukhopadhyay
Introduction
The Weibull Statistical Distribution
Weibull Analysis for HAp Coating
Weibull Analysis for C/C and C/SiC Composites
Conclusions
References
Substrate Effect in ThinFilm Measurements
Arjun Dey, I Neelakanta Reddy, N Sridhara, Anju M Pillai, Anand Kumar Sharma, Rajib Paul, A K Pal, and Anoop Kumar Mukhopadhyay
Introduction
Substrate Effect in Nanocomposite DLC Thin Films
Substrate Effect in Alumina Film
Conclusions
References
Future Scope of Novel Nanoindentation Technique
Arjun Dey and Anoop Kumar Mukhopadhyay
Introduction
Nanoindentation on Biological Materials and Nanostructures
In Situ Nanoindentation and Picoindentation
HighTemperature Nanoindentation
Properties other than Hardness and Modulus: a Direct
Measurement
References
Conclusions
Common Abbreviations
Index
