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Collision phenomena in liquids and solids /

A unique and in-depth discussion uncovering the unifying features of collision phenomena in liquids and solids, along with applications.

Detalles Bibliográficos
Clasificación:Libro Electrónico
Autores principales: Yarin, Alexander L., 1953- (Autor), Roisman, Ilia V., 1964- (Autor), Tropea, Cameron, 1954- (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Cambridge : Cambridge University Press, 2017.
Temas:
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Cover; Half title; Title; Copyright; Contents; Preface; 1 Introduction; 1.1 History and Outlook; 1.2 Dimensionless Groups; 1.3 Mass and Momentum Balance Equations; 1.4 Inviscid and Viscous Newtonian Fluids: The Incompressible Euler and Navier-Stokes Equations; 1.5 Impact at Liquid Surface and Equations of Impulsive Motion; 1.6 Boundary Layer Equations; 1.7 Quasi-one-dimensional and Lubrication Approximations in Problems on Drop Impact and Spreading; 1.8 Wettability; 1.9 Rheological Constitutive Equations of Non-Newtonian Fluids and Solids.
  • 1.10 Instabilities and Small Perturbations: Rayleigh Capillary Instability, Bending Instability, Kelvin-Helmholtz Instability, Rayleigh-Taylor Instability1.11 Total Mechanical Energy of Deforming Bodies: Where Is It Lost?; 1.12 References; 2 Selected Basic Flows and Forces; 2.1 Inviscid Flow in a Thin Film on a Wall; 2.2 Propagation of Kinematic Discontinuity; 2.3 External Irrotational Flows About Blunt Bodies; 2.4 Flows Past Arbitrary Axisymmetric Bodies of Revolution; 2.5 Transient Motion in Inviscid Fluids and Forces Associated with the Added Masses; 2.6 Friction and Shape Drag.
  • 2.7 Dynamics of a Rim Bounding a Free Liquid Sheet2.8 References; Part I Collision of Liquid Jets and Drops with a Dry Solid Wall; 3 Jet Impact onto a Solid Wall; 3.1 Normal and Inclined Impact of Inviscid Planar Jets onto a Plane Wall; 3.2 Normal Impact of Axisymmetric Impinging Jet; 3.3 Hydraulic Jump; 3.4 References; 4 Drop Impact onto a Dry Solid Wall; 4.1 Inviscid Flow on a Wall Generated by Inertia-Dominated Drop Impact; 4.2 Flow in a Spreading Viscous Drop, Including Description of Inclined Impact and Thermal Effects; 4.3 Initial Phase of Drop Impact; 4.4 Maximum Spreading Diameter.
  • 4.5 Time Evolution of the Drop Diameter: Rim Dynamics on a Wall4.6 Drop Impact onto Spherical Targets and Encapsulation; 4.7 Outcomes of Drop Impact onto a Dry Wall; 4.8 The Effect of Reduced Pressure of the Surrounding Gas; 4.9 Drop Impact onto Hot Rigid Surfaces; 4.10 Drop Impact with Solidification and Icing; 4.11 References; 5 Drop Impact onto Dry Surfaces with Complex Morphology; 5.1 Drop Splashing on Rough and Textured Surfaces; 5.2 Drop Impact Close to a Pore; 5.3 Drop Impact onto Porous Surfaces; 5.4 Nano-textured Surfaces: Drop Impact onto Suspended Nanofiber Membranes.
  • 5.5 Drop Impact onto Nanofiber Mats on Impermeable Substrates and Suppression of Splashing5.6 Hydrodynamic Focusing in Drop Impact onto Nanofiber Mats and Membranes; 5.7 Impact of Aqueous Suspension Drops onto Non-Wettable Porous Membranes: Hydrodynamic Focusing and Penetration of Nanoparticles; 5.8 Drop Impact onto Hot Surfaces Coated by Nanofiber Mats; 5.9 Nano-textured Surfaces: Suppression of the Leidenfrost Effect; 5.10 Bouncing Prevention: Dynamic Electrowetting; 5.11 References; Part II Drop Impacts onto Liquid Surfaces; 6 Drop Impacts with Liquid Pools and Layers.