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| Preface | p. xi |
| Acknowledgments | p. xiii |
| Materials Research Society Symposium Proceedings | p. xiv |
| Modeling and Simulations | |
| A Scaling Approach to Modeling Indentation Measurements | p. Q1.1 |
| Finite Element Modeling of Nanoindentation Measurements of Crystalline and Amorphous Si | p. Q1.2 |
| A Finite Element Study on the Nanoindentation of Thin Films | p. Q1.3 |
| Load-Displacement Behavior During Sharp Indentation of Viscous-Elastic-Plastic Materials | p. Q1.5 |
| Scanning Probe Methods | |
| Shear Modulation Force Microscopy Studies on Cross-Linked Elastomer Thin Films | p. Q2.2 |
| Thermomechanical Formation and Thermal Sensing of Nanometer-Scale Indentations in PMMA Thin Films for Parallel and Dense AFM Data Storage | p. Q2.3 |
| New Methods | |
| Sub-Micrometer Spatially Resolved Measurements of Mechanical Properties and Correlation to Microstructure and Composition | p. Q3.2 |
| On the Measurement of Stress-Strain Curves by Spherical Indentation | p. Q3.4 |
| Modulus Determination of Polymer Matrix Composites: Comparison of Nanoindentation and Dynamic Mechanical Analysis | p. Q3.5 |
| Determination of the Real Indenter Shape for Nanoindentation/Nanotribology Tests by Surface Metrological and Analytical Investigations | p. Q3.6 |
| 3D FIB and AFM Mapping of Nanoindentation Zones | p. Q3.7 |
| Three-Dimensional Contact Mechanics Studies of ZDOL Hard Disk Lubricants | p. Q3.9 |
| Deformation and Deformation Mechanisms | |
| Film Fracture Phenomena During Indentation | p. Q4.2 |
| Probing the Critical Stress Intensity Factor for Slip Transfer Across Grain Boundaries by Subgranular Indentation | p. Q4.10 |
| Deformation and Deformation Mechanisms II | |
| Dislocation Configurations Around Nanoindentations in Reconstructed Au(001) | p. Q5.2 |
| Microstructure and Mechanical Properties of Electroplated Cu Thin Films | p. Q5.3 |
| Mechanical Properties of As-Grown and Ion-Beam-Modified GaN Films | p. Q5.5 |
| Adhesion | |
| Adhesion Quantification of Post-CMP Copper to Amorphous SiN Passivation by Nanoindentation | p. Q6.1 |
| Adhesive Failure of a Thin Epoxy Film on an Aluminized Substrate | p. Q6.3 |
| Epoxy/Aluminum Adhesion as Measured by Contact Mechanics (JKR) in the Presence of an Organic Contaminant | p. Q6.4 |
| Adhesion of a Rigid Cylinder to an Incompressible Film | p. Q6.5 |
| Nanoindentation and Nanotribology | |
| The Effects of Creep on Elastic Modulus Measurement Using Nanoindentation | p. Q7.1 |
| Nanoindentation Evaluation of Brittle Films on Metals | p. Q7.6 |
| 3D Mapping of Subsurface Cracks in Alumina Using FIB | p. Q7.7 |
| Spherical Indentation and Flow Property Measurement-Finite Element Simulation | p. Q7.9 |
| Nanoindentation of Poly(methyl methacrylate) | p. Q7.10 |
| Correlation of Nanoindentation and Conventional Mechanical Property Measurements | p. Q7.11 |
| Mechanism of Al-Cu-Fe Quasicrystal Plastic Deformation Studied by Instrumented Sharp Indentation | p. Q7.12 |
| Plastic Zone Development Around Nanoindentations | p. Q7.14 |
| Determining the Area Function of Spherical Indenters for Nanoindentation | p. Q7.17 |
| Nanoscratch Deformation Response of Carbon Nitride Thin Films | p. Q7.19 |
| Effect of Film Thickness on the Nanoindentation Measurements of Hard Diamondlike Carbon Films Prepared by Pulsed Laser Deposition | p. Q7.20 |
| Nanoindentation Measurements of Mechanical Properties of Polystyrene Thin Films | p. Q7.21 |
| Nanoindentation of Pressure Quenched Fullerenes and Zirconium Metal From a Diamond Anvil Cell | p. Q7.24 |
| Limits of Strength in Indentation | |
| Physical Origin of a Size Effect in Nanoindentation | p. Q8.4 |
| Effect of Surface Steps on Dislocation Structure During Nanoindentation | p. Q8.8 |
| Identification of Pressure-Induced Phase Transformation Using Nanoindentation | p. Q8.9 |
| Mechanical Deformation of Crystalline Silicon During Nanoindentation | p. Q8.10 |
| An Assessment of the Mechanical Strengths of Aluminide-Based Thin Coatings | p. Q8.11 |
| Nanotribology | |
| Fundamental Aspects of Friction and Wear Contacts in W[left angle bracket]100[right angle bracket] Surfaces | p. Q9.1 |
| Nanomechanics Using an Ultra-Small Amplitude AFM | p. Q9.2 |
| Influence of Tipradius and Substrate on the Nanotribological Characterization of Thin DLC Coatings | p. Q9.3 |
| Computational Nanotribology: SAMs for MEMS | p. Q9.5 |
| Author Index | |
| Subject Index | |
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