Fundamentals of Nanoindentation and Nanotribology IV
Volume 1049
Part of MRS Proceedings
- Editors:
- Eric Le Bourhis, Université de Poitiers
- Dylan J. Morris
- Michelle L. Oyen, University of Cambridge
- Ruth Schwaiger, Forschungszentrum Karlsruhe
- Thorsten Staedler, Universität Siegen, Germany
- Date Published: May 2008
- availability: Available
- format: Hardback
- isbn: 9781558999893
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Nanoindentation and nanotribology are fundamental, evolving, and complementary disciplines within materials science. In recent years there has been rapid convergence of the biomechanical and materials disciplines, as well as explosive growth of the nanotube and nanostructured materials fields. The expansion of nanomechanical testing into these new fields has been accompanied by similarly rapid growth in our understanding of, and ability to perform, mechanical tests with ever-smaller forces and displacements. The understanding of fundamental mechanical measurement techniques must continue to advance to design new systems and materials to meet the challenges of technology. This book is a snapshot of the state of the art in nanoindentation and nanotribology, and highlights emerging topics including the development of new methods for characterizing nanoscale mechanical and tribological properties. Additional topics include: size effects and indentation of thin films; nanotribology and friction; modeling, simulation and analysis of indentation data and nanomechanics of polymers, time-dependent characterization.
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×Product details
- Date Published: May 2008
- format: Hardback
- isbn: 9781558999893
- length: 183 pages
- dimensions: 235 x 157 x 15 mm
- weight: 0.4kg
- availability: Available
Table of Contents
Preface
Acknowledgments
Part I. Nanomechanics, Tribology and Nanostructures:
1. Comprehensive mechanical and tribological characterization of ultra-thin-films Norm Gitis, Michael Vinogradov, Ilja Hermann and Suresh Kuiry
2. Mechanical response of a single and released InP membrane Eric Le Bourhuis and Gilles Patriarche
3. Indentation response of nanostructured turfs A. A. Zbib, S. Dj. Mesarovic, D. F. Bahr, E. T. Lilleodden, J. Jiao and D. McClain
4. Effect of hydrostatic pressure on indentation modulus W. M. Mook and W. W. Gerberich
Part II. Size Effects and Indentation of Thin Films:
5. Microstructural investigation of the deformation zone below nano-indents in copper Martin Rester, Christian Motz and Reinhard Pippan
6. Microstructure and mechanical properties characterization of nanocrystalline copper films Nursiani Indah Tjahyono and Yu Lung Chiu
7. Mechanical properties of 3C-SiC films for MEMS applications Jayadeep Deva Reddy, Alex A. Volinsky, Christopher L. Frewin, Chris Locke and Stephen E. Sandow
8. Strength measurement in brittle thin films Oscar Borrero-Lopez, Mark Hoffman, Avi Bendavid and Phil J. Martin
Part III. Nanotribology and Friction:
9. Measurement of ultrathin film mechanical properties by integrated nano-scratch/indentation approach Ashraf Bastawros, Wei Che and Abhijit Chandra
10. Theory of lubrication due to poly-electrolyte polymer brushes Jeffrey B. Sokoloff
11. Tip-induced calcite single crystal nanowear Ramakrishna Gunda and Alex A. Volinsky
12. Study on the damage mechanisms in WC-Co hard metals during scratch testing Siphilisiwe Mdlovu, Karsten Durst, Heinz Werner Hoeppel and Mathias Goeken
Part IV. Modeling, Simulation and Analysis of Indentation Data:
13. Mapping of the initial volume at the onset of plasticity in nanoindentation T. T. Zhu, K. M. Y. P'ng, M. Hopkinson, A. J. Bushby and D. J. Dunstan
14. Quasi-static and oscillatory indentation in linear viscoelastic solids Yang-Tse Cheng and Che-Min Cheng
15. Indentation of nonlinearly viscoelastic solids Michaelle L. Oyen
16. Determination of residual stress and yield stress simultaneously by indentation method with dual indenters Baoxing Xu, Xinmei Wang and Zhufeng Yue
17. Instrumented indentation contact with sharp probes of varying acuity Dylan J. Morris
18. An algorithm to determine the plastic properties of materials based on the loading data in single sharp indentation Akio Yonezu, Hiroyuki Hirakata and Kohji Minoshima
19. Plasticity characteristics obtained through instrumental indentation Yuliy Milman, Sergey Dub and Alex Golubenko
20. Nanoindentation analysis of plasticity evolution during spherical microindentation of bulk metallic glass Byung-Gil Yoo and Jae-il Jang
21. Reverse plasticity in nanindentation Yongjiang Huang, Nursiani Indah Tjahyono, Jun Shen and Yu Lung Chiu
22. Uniaxial compression behavior of bulk nano-twinned gold from moecular dynamics simulation Chuang Deng and Frederic Sansoz
Part V. Nonomechanics of Polymers, Time Dependent Characterization:
23. Interfacial characterization of multiple layer coatings on thermoplastic olefins (TPO) Aaron M. Forster, Chris A. Michaels, Justin Lucas and Lipiin Sung
24. Viscoelastic behavior of a centrally loaded circular film being clamped at the circumference Michaelle L. Oyen, Kuo-kang Liu and Kai-tak Wan
25. Analysis of indentation creep D. S. Stone and A. A. Elmustafa
26. Haasen plot activation analysis of constant-force indentation creep in FCC systems Vineet Bhakhri and Robert J. Klassen
27. Mechanical properties of sputtered silicon oxynitride films by nanoindentation Yan Liu, I-Kuan Lin and Xin Zhang
Author index
Subject index.
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