The Resource Mathematical fluid dynamics, present and future : Tokyo, Japan, November 2014, Yoshihiro Shibata, Yukihito Suzuki, editors

Mathematical fluid dynamics, present and future : Tokyo, Japan, November 2014, Yoshihiro Shibata, Yukihito Suzuki, editors

Label
Mathematical fluid dynamics, present and future : Tokyo, Japan, November 2014
Title
Mathematical fluid dynamics, present and future
Title remainder
Tokyo, Japan, November 2014
Statement of responsibility
Yoshihiro Shibata, Yukihito Suzuki, editors
Creator
Contributor
Editor
Subject
Genre
Language
eng
Summary
This volume presents original papers ranging from an experimental study on cavitation jets to an up-to-date mathematical analysis of the Navier-Stokes equations for free boundary problems, reflecting topics featured at the International Conference on Mathematical Fluid Dynamics, Present and Future, held 11-14 November 2014 at Waseda University in Tokyo. The contributions address subjects in one- and two-phase fluid flows, including cavitation, liquid crystal flows, plasma flows, and blood flows. Written by internationally respected experts, these papers highlight the connections between mathematical, experimental, and computational fluid dynamics. The book is aimed at a wide readership in mathematics and engineering, including researchers and graduate students interested in mathematical fluid dynamics
Member of
Cataloging source
N$T
Dewey number
  • 620.1/064015118
  • 510
Index
no index present
LC call number
  • TA357
  • QA1-939
Literary form
non fiction
http://bibfra.me/vocab/lite/meetingDate
2014
http://bibfra.me/vocab/lite/meetingName
International Conference on Mathematical Fluid Dynamics, Present and Future
Nature of contents
  • dictionaries
  • bibliography
http://library.link/vocab/relatedWorkOrContributorName
  • Shibata, Yoshihiro
  • Suzuki, Yukihito
Series statement
Springer proceedings in mathematics & statistics,
Series volume
volume 183
http://library.link/vocab/subjectName
  • Fluid dynamics
  • Fluid dynamics
  • TECHNOLOGY & ENGINEERING
  • TECHNOLOGY & ENGINEERING
  • Fluid dynamics
  • Fluid dynamics
  • Mathematics
  • Partial Differential Equations
  • Engineering Fluid Dynamics
  • Mathematical Applications in the Physical Sciences
  • Mechanics of fluids
  • Mathematical modelling
  • Differential calculus & equations
Label
Mathematical fluid dynamics, present and future : Tokyo, Japan, November 2014, Yoshihiro Shibata, Yukihito Suzuki, editors
Link
https://ezproxy.lib.ou.edu/login?url=http://link.springer.com/10.1007/978-4-431-56457-7
Instantiates
Publication
Antecedent source
unknown
Bibliography note
Includes bibliographical references
Carrier category
online resource
Carrier category code
  • cr
Carrier MARC source
rdacarrier
Color
multicolored
Content category
text
Content type code
  • txt
Content type MARC source
rdacontent
Contents
  • Preface; Acknowledgements; Contents; Contributors; Part I Multiphase Flows; 1 Nonconvergence of the Capillary Stress Functional for Solutions of the Convective Cahn-Hilliard Equation; 1.1 Introduction; 1.2 Notation and Basic Assumptions; 1.3 Nonconvergence Result; References; 2 On the Interface Formation Model for Dynamic Triple Lines; 2.1 Introduction; 2.2 Integral Balances; 2.3 Transport Theorems; 2.4 Local Balances; 2.5 Entropy Production and Closure Relations; 2.6 Isothermal Case with Vanishing Triple Line Mass; 2.7 Thermodynamical Consistency and Equilibria; References
  • 3 Global Solvability of the Problem on Two-Phase Capillary Fluid Motion in the Oberbeck -- Boussinesq Approximation3.1 Statement of the Problem and the Main Result; 3.2 An Energy Estimate of the Solution; 3.3 Linearized Problems; 3.4 Global Solvability of the Problem (3.1), (3.4), (3.3); 3.4.1 Conclusions; References; 4 Stability of Steady Flow Past a Rotating Body; 4.1 Motivation and Introduction; 4.2 Auxiliary Results; 4.3 The Main Theorem on Stability; References; 5 Asymptotic Structure of Steady Stokes Flow Around a Rotating Obstacle in Two Dimensions; 5.1 Introduction; 5.2 Results
  • 5.3 Fundamental Solution5.4 Proof of Theorem 5.2.1; 5.5 Proof of Theorem 5.2.2; References; 6 Toward Understanding Global Flow Structure; 6.1 Introduction; 6.2 Phenomena; 6.2.1 Localized Convection Patterns in Binary Fluid Convection; 6.2.2 Localized Convection Patterns in Bioconvection; 6.2.3 Surface Switching; 6.3 Analysis Methods; 6.3.1 Orbit Analysis Applying Covariant Lyapunov Analysis; 6.3.2 Generating Cellular Automata Rule from Measurement Data Alone; 6.4 Concluding Remarks; References; 7 Mathematical and Numerical Analysis of the Rayleigh-Plesset and the Keller Equations
  • 7.1 Introduction7.2 Mathematical Models for Motion of a Spherical Bubble; 7.2.1 The Rayleigh-Plesset Equation; 7.2.2 The Rayleigh-Plesset-Keller Equation; 7.3 Mathematical Analysis; 7.4 A Hamiltonian Formulation of the Rayleigh-Plesset-Keller Equation; 7.4.1 A Hamiltonian Formulation of the Rayleigh-Plesset Equation; 7.4.2 A Hamiltonian Formulation of the Keller-Herring Equation; 7.5 Discrete Gradient Schemes for the Rayleigh-Plesset and Keller Equations; 7.6 Numerical Results; 7.6.1 The Inviscid Rayleigh-Plesset Equation; 7.6.2 The Keller Equation; 7.7 Concluding Remarks; References
  • 8 On the Amplitude Equation of Approximate Surface Waves on the Plasma-Vacuum Interface8.1 Introduction; 8.2 The Plasma-Vacuum Interface Problem; 8.3 The Asymptotic Expansion; 8.4 The First Order Equations; 8.5 The Second Order Equations; 8.5.1 The Second Order Equations in the Plasma Region; 8.5.2 The Second Order Equations in Vacuum; 8.5.3 The Second Order Jump Conditions; 8.5.4 The Kernel; 8.6 Noncanonical Variables and Well-Posedness; 8.6.1 Well-Posedness of the Amplitude Equation; 8.6.2 Regularity of the First Order Terms U(1), V(1); References
Dimensions
unknown
Extent
1 online resource.
File format
unknown
Form of item
online
Isbn
9784431564553
Level of compression
unknown
Media category
computer
Media MARC source
rdamedia
Media type code
  • c
Note
SpringerLink
Other control number
10.1007/978-4-431-56457-7
Quality assurance targets
not applicable
Reformatting quality
unknown
Sound
unknown sound
Specific material designation
remote
System control number
  • (OCoLC)965375114
  • (OCoLC)ocn965375114
Label
Mathematical fluid dynamics, present and future : Tokyo, Japan, November 2014, Yoshihiro Shibata, Yukihito Suzuki, editors
Link
https://ezproxy.lib.ou.edu/login?url=http://link.springer.com/10.1007/978-4-431-56457-7
Publication
Antecedent source
unknown
Bibliography note
Includes bibliographical references
Carrier category
online resource
Carrier category code
  • cr
Carrier MARC source
rdacarrier
Color
multicolored
Content category
text
Content type code
  • txt
Content type MARC source
rdacontent
Contents
  • Preface; Acknowledgements; Contents; Contributors; Part I Multiphase Flows; 1 Nonconvergence of the Capillary Stress Functional for Solutions of the Convective Cahn-Hilliard Equation; 1.1 Introduction; 1.2 Notation and Basic Assumptions; 1.3 Nonconvergence Result; References; 2 On the Interface Formation Model for Dynamic Triple Lines; 2.1 Introduction; 2.2 Integral Balances; 2.3 Transport Theorems; 2.4 Local Balances; 2.5 Entropy Production and Closure Relations; 2.6 Isothermal Case with Vanishing Triple Line Mass; 2.7 Thermodynamical Consistency and Equilibria; References
  • 3 Global Solvability of the Problem on Two-Phase Capillary Fluid Motion in the Oberbeck -- Boussinesq Approximation3.1 Statement of the Problem and the Main Result; 3.2 An Energy Estimate of the Solution; 3.3 Linearized Problems; 3.4 Global Solvability of the Problem (3.1), (3.4), (3.3); 3.4.1 Conclusions; References; 4 Stability of Steady Flow Past a Rotating Body; 4.1 Motivation and Introduction; 4.2 Auxiliary Results; 4.3 The Main Theorem on Stability; References; 5 Asymptotic Structure of Steady Stokes Flow Around a Rotating Obstacle in Two Dimensions; 5.1 Introduction; 5.2 Results
  • 5.3 Fundamental Solution5.4 Proof of Theorem 5.2.1; 5.5 Proof of Theorem 5.2.2; References; 6 Toward Understanding Global Flow Structure; 6.1 Introduction; 6.2 Phenomena; 6.2.1 Localized Convection Patterns in Binary Fluid Convection; 6.2.2 Localized Convection Patterns in Bioconvection; 6.2.3 Surface Switching; 6.3 Analysis Methods; 6.3.1 Orbit Analysis Applying Covariant Lyapunov Analysis; 6.3.2 Generating Cellular Automata Rule from Measurement Data Alone; 6.4 Concluding Remarks; References; 7 Mathematical and Numerical Analysis of the Rayleigh-Plesset and the Keller Equations
  • 7.1 Introduction7.2 Mathematical Models for Motion of a Spherical Bubble; 7.2.1 The Rayleigh-Plesset Equation; 7.2.2 The Rayleigh-Plesset-Keller Equation; 7.3 Mathematical Analysis; 7.4 A Hamiltonian Formulation of the Rayleigh-Plesset-Keller Equation; 7.4.1 A Hamiltonian Formulation of the Rayleigh-Plesset Equation; 7.4.2 A Hamiltonian Formulation of the Keller-Herring Equation; 7.5 Discrete Gradient Schemes for the Rayleigh-Plesset and Keller Equations; 7.6 Numerical Results; 7.6.1 The Inviscid Rayleigh-Plesset Equation; 7.6.2 The Keller Equation; 7.7 Concluding Remarks; References
  • 8 On the Amplitude Equation of Approximate Surface Waves on the Plasma-Vacuum Interface8.1 Introduction; 8.2 The Plasma-Vacuum Interface Problem; 8.3 The Asymptotic Expansion; 8.4 The First Order Equations; 8.5 The Second Order Equations; 8.5.1 The Second Order Equations in the Plasma Region; 8.5.2 The Second Order Equations in Vacuum; 8.5.3 The Second Order Jump Conditions; 8.5.4 The Kernel; 8.6 Noncanonical Variables and Well-Posedness; 8.6.1 Well-Posedness of the Amplitude Equation; 8.6.2 Regularity of the First Order Terms U(1), V(1); References
Dimensions
unknown
Extent
1 online resource.
File format
unknown
Form of item
online
Isbn
9784431564553
Level of compression
unknown
Media category
computer
Media MARC source
rdamedia
Media type code
  • c
Note
SpringerLink
Other control number
10.1007/978-4-431-56457-7
Quality assurance targets
not applicable
Reformatting quality
unknown
Sound
unknown sound
Specific material designation
remote
System control number
  • (OCoLC)965375114
  • (OCoLC)ocn965375114

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