| Description |
1 online resource (533 p.) |
| Series |
Advanced structured materials ; v.195 |
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Advanced structured materials ; 195.
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| Contents |
Intro -- Preface I -- Preface II -- In Memory of Igor Sevostianov -- Contents -- 1 Micromechanical Modeling of Non-linear Stress-Strain Behavior of Polycrystalline Microcracked Ceramics -- 1.1 Introduction -- 1.2 Materials and Experiments -- 1.2.1 [beta]-Eucryptite Subjected to Cyclic Tensile Loading of Increasing Amplitude -- 1.2.2 Aluminum Titanate Subjected to Compressive Interrupted Loading -- 1.3 Micromechanical Explanation and Modeling -- 1.3.1 Uniaxial Compression -- 1.3.2 Uniaxial Tension -- 1.4 Concluding Remarks -- References |
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2 Shamrovskii's Version of the Refined Dynamical Plate Theory -- 2.1 Introduction. Uflyand-Mindlin Theory: History of Question -- 2.2 Newton Polygon and Its Generalizations -- 2.3 The Idea of Shamrovskii's Algorithm -- 2.4 Shamrovskii's Refined Plate Theory -- 2.5 Conclusion -- 2.6 Brief Biography of A. D. Shamrovskii -- References -- 3 Time-Resolved Multifractal Analysis of Electron Beam Induced Piezoelectric Polymer Fiber Dynamics: Towards Multiscale Thread-Based Microfluidics or Acoustofludics |
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3.1 From Charging of the SEM Samples to the Formation of SAW Potential Contrasts and Micromechanical Local Movements in Piezoelectric Fiber Samples, Induced by the Acoustic Waves -- 3.2 The Possibility of Designing Electron Beam-Controlled Acoustofluidics, Including Electron Beam-Controlled Thread-Based Micro-Acoustofluidics -- 3.3 Methods for Studying the Dynamics of PVDF Fibers -- 3.4 Investigation of the Characteristic Dimensions of Piezoelectric Polymer Fibers -- 3.5 Results and Discussion -- References |
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4 Simple Coarse-Grained Model of the Zebrafish Embryonic Aorta Suggesting the Mechanism Driving Shape Changes During Stem Cell Production -- 4.1 Introduction -- 4.2 The HSC Production Process in Zebrafish -- 4.3 Model of the Dorsal Aorta -- 4.4 Results and Discussion -- 4.5 Conclusion -- References -- 5 Averaging-Based Approach to Toughness Homogenisation for Radial Hydraulic Fracture -- 5.1 Introduction -- 5.2 Problem Formulation -- 5.2.1 The Radial Model with Inhomogeneous Toughness -- 5.2.2 Form of the Material Toughness -- 5.2.3 Parameterising the Fracture Regime |
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5.2.4 Numerical Algorithm and Behaviour of the Key Parameters -- 5.3 Comparison of Homogenisation Strategies -- 5.3.1 The Maximum Toughness and Temporal-Averaging Approaches -- 5.3.2 Results for Balanced Toughness Distributions -- 5.3.3 Results for Unbalanced Layering -- 5.4 Conclusions -- References -- 6 Towards Multi-Angle Multi-Channel Optical Porometry and Scanning Electron Microscopic Porometry of LDPE Composites Including Geotechnical Biodegradable Ones -- 6.1 Introduction -- 6.2 Materials and Methods -- 6.2.1 Materials and Sample Preparation |
| Summary |
This book is published on dedication of Prof. Dr. Igor Sevostianov who passed away in 2021. He was a great Russian-American scientist who made significant contributions in the field of mechanics of heterogeneous media. This book contains research papers from his friends and colleagues in this research field |
| Notes |
6.2.2 Dynamical Multi-Channel Multi-Angle Optical Porometry |
| Bibliography |
Includes bibliographical references |
| Notes |
Online resource; title from PDF title page (SpringerLink, viewed July 20, 2023) |
| Subject |
Inhomogeneous materials -- Mechanical properties
|
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Mechanics, Applied.
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Inhomogeneous materials -- Mechanical properties
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Mechanics, Applied
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| Form |
Electronic book
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| Author |
Altenbach, Holm, 1956-
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Bruno, Giovanni
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Eremeyev, Victor A.
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Gutkin, M. I︠U︡. (Mikhail I︠U︡rʹevich)
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Müller, Wolfgang H., 1959-
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| ISBN |
9783031287442 |
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3031287444 |
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