Lucas Goehring, Akio Nakahara, Tapati Dutta, So Kitsunezaki, Sujata Tarafdar
Desiccation Cracks and their Patterns (eBook, PDF)
Formation and Modelling in Science and Nature
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Lucas Goehring, Akio Nakahara, Tapati Dutta, So Kitsunezaki, Sujata Tarafdar
Desiccation Cracks and their Patterns (eBook, PDF)
Formation and Modelling in Science and Nature
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Bringing together basic ideas, classical theories, recent experimental and theoretical aspects, this book explains desiccation cracks from simple, easily-comprehensible cases to more complex, applied situations. The ideal team of authors, combining experimental and theoretical backgrounds, and with experience in both physical and earth sciences, discuss how the study of cracks can lead to the design of crack-resistant materials, as well as how cracks can be grown to generate patterned surfaces at the nano- and micro-scales. Important research and recent developments on tailoring desiccation…mehr
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Bringing together basic ideas, classical theories, recent experimental and theoretical aspects, this book explains desiccation cracks from simple, easily-comprehensible cases to more complex, applied situations. The ideal team of authors, combining experimental and theoretical backgrounds, and with experience in both physical and earth sciences, discuss how the study of cracks can lead to the design of crack-resistant materials, as well as how cracks can be grown to generate patterned surfaces at the nano- and micro-scales. Important research and recent developments on tailoring desiccation cracks by different methods are covered, supported by straightforward, yet deep theoretical models. Intended for a broad readership spanning physics, materials science, and engineering to the geosciences, the book also includes additional reading especially for students engaged in pattern formation research.
Produktdetails
- Produktdetails
- Verlag: Wiley-VCH
- Seitenzahl: 368
- Erscheinungstermin: 12. Februar 2015
- Englisch
- ISBN-13: 9783527671953
- Artikelnr.: 42480975
- Verlag: Wiley-VCH
- Seitenzahl: 368
- Erscheinungstermin: 12. Februar 2015
- Englisch
- ISBN-13: 9783527671953
- Artikelnr.: 42480975
Sujata Tarafdar joined the faculty of Jadavpur University, Kolkata, in 1990 and at present is a Professor of Physics there. Her research interest covers: fractals and disordered systems, pattern formation in nature, viscous fingering and crack networks, soft condensed matter, porous media and polymer electrolytes. She is coordinator of the Condensed Matter Physics Research Centre, Jadavpur University and general secretary of the Indian Society of Nonlinear Analysts. She is on the editorial board of Frontiers in Physics (Nature publishing group) as a review editor. Akio Nakahara is the Associate Professor of Physics at Nihon University, Japan. Having obtained his PhD degree at Kyushu University, he spent four years as a PostDoc at Chuo University, and then joined Nihon University. He has worked on the Physics of Pattern Formation, and recently he found a method to control morphology of crack patterns using memory effect of plastic fluid. Tapati Dutta is an Associate Professor in the Physics Department of St. Xavier's College, Kolkata, India. Having completed her Master's degree from Calcutta University and her PhD from Jadavpur University, she joined the Physics Department of St. Xavier's College in 1990 and has been continuing since then. She formerly was Head of the Department and is at present Dean of Research of St. Xavier's College. She is a member of the academic committee of the Condensed Mater Physics Research Centre of Jadavpur University. Dr. Dutta is also a member of the Indian Society of Non-linear Analysts. Her research interests are condensed matter physics and nonlinear dynamics. So Kitsunezaki is an Associate professor of the department of physics at Nara women's university, Japan. After receiving his PhD at Kyoto University in 1997, he has taught in the university until now. He specialises in nonlinear dynamics and pattern formation. He studied the pattern formation of mud cracks and columnar joints of starch, theoretically and experimentally, and his current interests include the fracture mechanics of paste and wet granular materials. Lucas Goehring leads a research group at the Max Planck Institute for Dynamics and Self-Organization, and teaches at the nearby Georg-August Universität Göttingen. He obtained his PhD at the University of Toronto, for his work on columnar jointing, and was recently a Fellow of Wolfson College, at the University of Cambridge. There he worked on the drying and cracking of colloidal films. His current research interests involve pattern formation, multi-phase flow, soft-matter physics, and geophysics.
INTRODUCTION Basic Conditions for Crack Formation Linear Elasticity Linear Elastic Fracture Mechanics: Griffith and Irwin Poro-Elasticity Process of Desiccation Drying Regimes, Constant Rate/Falling Rate Periods Water Transport in a Drying Soil: Basics of Capillary Flow and Vapor Transport How Capillary Forces give Rise to Stresses Energy Considerations Driving Force for Cracking during Drying Length Scales: through-Thickness Cracks, Channel Cracks, Interface Cracks, etc. Fracture Saturation - Crack Spacing is similar to Layer Thickness Non-Linear and Dissipative Effects DYNAMICS AND PATTERNS Propagation of a Crack - Crack Velocity - self-affine Structure The Crack Network - 2 dimensional View - self Similarity - fractal Dimension Instabilities: wavy Cracks, en Echelon/en passant Cracks, Star-Cracks, Wing-Cracks, etc. Transition from Dendrites to Fracture Cracks in 3 Dimensions - geological Formations - Cracks in Soil - Cracking versus Peeling Columnar Joints - Desiccation induced analogue produced in the Lab Columnar Joints in Lava and Starch, Summary Scaling: Spacing related to effective Layer Thickness, set by Advection-Diffusion. Ordering - Cracks interact and evolve from Squares to Hexagons. Extensions to other Patterns: Permafrost/polygonal Terrain, evolving Mud Cracks, Surface Cracks in erosional Systems. Practical Applications, estimating Cooling Rate, Conditions during Formation. THEORETICAL ANALYSIS AND MODELING Channeling Cracks Special Solutions; Relation of Channeling to Tunneling cracks Effects of Substrate Elasticity, Dunders Parameters (Non-Dimensionalization) TAILORING CRACK PATTERNS Memory Effect - Effect of Vibration, Rotation and Flow Effect of Fields - Electric - DC and AC and Magnetic NUMERICAL METHODS: Random Fuse Models Spring Network Models Other Models POSSIBLE APPLICATIONS OF STUDY OF CRACKS Designing Crack resistant Materials and Composites Controlling Crack Formation for Micro to Nano-Scale Patterning CONCLUSION
INTRODUCTION Basic Conditions for Crack Formation Linear Elasticity Linear Elastic Fracture Mechanics: Griffith and Irwin Poro-Elasticity Process of Desiccation Drying Regimes, Constant Rate/Falling Rate Periods Water Transport in a Drying Soil: Basics of Capillary Flow and Vapor Transport How Capillary Forces give Rise to Stresses Energy Considerations Driving Force for Cracking during Drying Length Scales: through-Thickness Cracks, Channel Cracks, Interface Cracks, etc. Fracture Saturation - Crack Spacing is similar to Layer Thickness Non-Linear and Dissipative Effects DYNAMICS AND PATTERNS Propagation of a Crack - Crack Velocity - self-affine Structure The Crack Network - 2 dimensional View - self Similarity - fractal Dimension Instabilities: wavy Cracks, en Echelon/en passant Cracks, Star-Cracks, Wing-Cracks, etc. Transition from Dendrites to Fracture Cracks in 3 Dimensions - geological Formations - Cracks in Soil - Cracking versus Peeling Columnar Joints - Desiccation induced analogue produced in the Lab Columnar Joints in Lava and Starch, Summary Scaling: Spacing related to effective Layer Thickness, set by Advection-Diffusion. Ordering - Cracks interact and evolve from Squares to Hexagons. Extensions to other Patterns: Permafrost/polygonal Terrain, evolving Mud Cracks, Surface Cracks in erosional Systems. Practical Applications, estimating Cooling Rate, Conditions during Formation. THEORETICAL ANALYSIS AND MODELING Channeling Cracks Special Solutions; Relation of Channeling to Tunneling cracks Effects of Substrate Elasticity, Dunders Parameters (Non-Dimensionalization) TAILORING CRACK PATTERNS Memory Effect - Effect of Vibration, Rotation and Flow Effect of Fields - Electric - DC and AC and Magnetic NUMERICAL METHODS: Random Fuse Models Spring Network Models Other Models POSSIBLE APPLICATIONS OF STUDY OF CRACKS Designing Crack resistant Materials and Composites Controlling Crack Formation for Micro to Nano-Scale Patterning CONCLUSION