Info
- Utilizzare la checkbox di selezione a fianco di ciascun documento per attivare le funzionalità di stampa, invio email, download nei formati disponibili del (i) record.
Rotating thermal flows in natural and industrial processes [[electronic resource] /] / Marcello Lappa
| Rotating thermal flows in natural and industrial processes [[electronic resource] /] / Marcello Lappa |
| Autore | Lappa Marcello |
| Pubbl/distr/stampa | Hoboken, N.J., : Wiley, 2012 |
| Descrizione fisica | 1 online resource (542 p.) |
| Disciplina | 536/.2 |
| Soggetto topico |
Heat - Transmission
Rotating masses of fluid |
| ISBN |
1-283-64505-X
1-118-34238-0 1-118-34240-2 1-118-34241-0 |
| Classificazione | SCI065000 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Rotating Thermal Flows; Contents; Preface; Acknowledgements; Chapter 1 Equations, General Concepts and Nondimensional Numbers; 1.1 The Navier-Stokes and Energy Equations; 1.1.1 The Continuity Equation; 1.1.2 The Momentum Equation; 1.1.3 The Total Energy Equation; 1.1.4 The Budget of Internal Energy; 1.1.5 Closure Models; 1.2 Some Considerations about the Dynamics of Vorticity; 1.2.1 Vorticity and Circulation; 1.2.2 Vorticity in Two Dimensions; 1.2.3 Vorticity Over a Spherical Surface; 1.2.4 The Curl of the Momentum Equation; 1.3 Incompressible Formulation; 1.4 Buoyancy Convection
1.4.1 The Boussinesq Model 1.4.2 The Grashof and Rayleigh Numbers; 1.5 Surface-Tension-Driven Flows; 1.5.1 Stress Balance; 1.5.2 The Reynolds and Marangoni Numbers; 1.5.3 The Microgravity Environment; 1.6 Rotating Systems: The Coriolis and Centrifugal Forces; 1.6.1 Generalized Gravity; 1.6.2 The Coriolis, Taylor and Rossby Numbers; 1.6.3 The Geostrophic Flow Approximation; 1.6.4 The Taylor-Proudman Theorem; 1.6.5 Centrifugal and Stratification Effects: The Froude Number; 1.6.6 The Rossby Deformation Radius; 1.7 Some Elementary Effects due to Rotation 1.7.1 The Origin of Cyclonic and Anticyclonic flows 1.7.2 The Ekman Layer; 1.7.3 Ekman Spiral; 1.7.4 Ekman Pumping; 1.7.5 The Stewartson Layer; Chapter 2 Rayleigh-B ́enard Convection with Rotation; 2.1 Rayleigh-B ́enard Convection with Rotation in Infinite Layers; 2.1.1 Linear Stability Analysis; 2.1.2 Asymptotic Analysis; 2.2 The Kuppers-Lortz Instability and Domain Chaos; 2.3 Patterns with Squares; 2.4 Typical Phenomena for Pr = 1 and Small Values of the Coriolis Number; 2.4.1 Spiral Defect Chaos and Chiral Symmetry; 2.4.2 The Interplay between the Busse Balloon and the KL Instability 2.5 The Low-Pr Hopf Bifurcation and Mixed States 2.5.1 Standing and Travelling Rolls; 2.5.2 Patterns with the Symmetry of Square and Hexagonal Lattices; 2.5.3 Other Asymptotic Analyses; 2.5.4 Nature and Topology of the Bifurcation Lines in the Space of Parameters (τ,Pr); 2.6 Laterally Confined Convection; 2.6.1 The First Bifurcation and Wall Modes; 2.6.2 The Second Bifurcation and Bulk Convection; 2.6.3 Square Patterns Driven by Nonlinear Interactions between Bulk and Wall Modes; 2.6.4 Square Patterns as a Nonlinear Combination of Bulk Fourier Eigenmodes; 2.6.5 Higher-Order Bifurcations 2.7 Centrifugal Effects 2.7.1 Stably Thermally Stratified Systems; 2.7.2 Interacting Thermogravitational and Centrifugally Driven Flows; 2.7.3 The Effect of the Centrifugal Force on Domain Chaos; 2.8 Turbulent Rotating RB Convection; 2.8.1 The Origin of the Large-scale Circulation; 2.8.2 Rotating Vortical Plumes; 2.8.3 Classification of Flow Regimes; 2.8.4 Suppression of Large-scale Flow and Heat Transfer Enhancement; 2.8.5 Prandtl Number Effects; Chapter 3 Spherical Shells, Rossby Waves and Centrifugally Driven Thermal Convection; 3.1 The Coriolis Effect in Atmosphere Dynamics 3.1.1 The Origin of the Zonal Winds |
| Record Nr. | UNINA-9910138869703321 |
Lappa Marcello
|
||
| Hoboken, N.J., : Wiley, 2012 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Rotating thermal flows in natural and industrial processes / / Marcello Lappa
| Rotating thermal flows in natural and industrial processes / / Marcello Lappa |
| Autore | Lappa Marcello |
| Edizione | [1st ed.] |
| Pubbl/distr/stampa | Hoboken, N.J., : Wiley, 2012 |
| Descrizione fisica | 1 online resource (542 p.) |
| Disciplina | 536/.2 |
| Soggetto topico |
Heat - Transmission
Rotating masses of fluid |
| ISBN |
1-283-64505-X
1-118-34238-0 1-118-34240-2 1-118-34241-0 |
| Classificazione | SCI065000 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Rotating Thermal Flows; Contents; Preface; Acknowledgements; Chapter 1 Equations, General Concepts and Nondimensional Numbers; 1.1 The Navier-Stokes and Energy Equations; 1.1.1 The Continuity Equation; 1.1.2 The Momentum Equation; 1.1.3 The Total Energy Equation; 1.1.4 The Budget of Internal Energy; 1.1.5 Closure Models; 1.2 Some Considerations about the Dynamics of Vorticity; 1.2.1 Vorticity and Circulation; 1.2.2 Vorticity in Two Dimensions; 1.2.3 Vorticity Over a Spherical Surface; 1.2.4 The Curl of the Momentum Equation; 1.3 Incompressible Formulation; 1.4 Buoyancy Convection
1.4.1 The Boussinesq Model 1.4.2 The Grashof and Rayleigh Numbers; 1.5 Surface-Tension-Driven Flows; 1.5.1 Stress Balance; 1.5.2 The Reynolds and Marangoni Numbers; 1.5.3 The Microgravity Environment; 1.6 Rotating Systems: The Coriolis and Centrifugal Forces; 1.6.1 Generalized Gravity; 1.6.2 The Coriolis, Taylor and Rossby Numbers; 1.6.3 The Geostrophic Flow Approximation; 1.6.4 The Taylor-Proudman Theorem; 1.6.5 Centrifugal and Stratification Effects: The Froude Number; 1.6.6 The Rossby Deformation Radius; 1.7 Some Elementary Effects due to Rotation 1.7.1 The Origin of Cyclonic and Anticyclonic flows 1.7.2 The Ekman Layer; 1.7.3 Ekman Spiral; 1.7.4 Ekman Pumping; 1.7.5 The Stewartson Layer; Chapter 2 Rayleigh-B ́enard Convection with Rotation; 2.1 Rayleigh-B ́enard Convection with Rotation in Infinite Layers; 2.1.1 Linear Stability Analysis; 2.1.2 Asymptotic Analysis; 2.2 The Kuppers-Lortz Instability and Domain Chaos; 2.3 Patterns with Squares; 2.4 Typical Phenomena for Pr = 1 and Small Values of the Coriolis Number; 2.4.1 Spiral Defect Chaos and Chiral Symmetry; 2.4.2 The Interplay between the Busse Balloon and the KL Instability 2.5 The Low-Pr Hopf Bifurcation and Mixed States 2.5.1 Standing and Travelling Rolls; 2.5.2 Patterns with the Symmetry of Square and Hexagonal Lattices; 2.5.3 Other Asymptotic Analyses; 2.5.4 Nature and Topology of the Bifurcation Lines in the Space of Parameters (τ,Pr); 2.6 Laterally Confined Convection; 2.6.1 The First Bifurcation and Wall Modes; 2.6.2 The Second Bifurcation and Bulk Convection; 2.6.3 Square Patterns Driven by Nonlinear Interactions between Bulk and Wall Modes; 2.6.4 Square Patterns as a Nonlinear Combination of Bulk Fourier Eigenmodes; 2.6.5 Higher-Order Bifurcations 2.7 Centrifugal Effects 2.7.1 Stably Thermally Stratified Systems; 2.7.2 Interacting Thermogravitational and Centrifugally Driven Flows; 2.7.3 The Effect of the Centrifugal Force on Domain Chaos; 2.8 Turbulent Rotating RB Convection; 2.8.1 The Origin of the Large-scale Circulation; 2.8.2 Rotating Vortical Plumes; 2.8.3 Classification of Flow Regimes; 2.8.4 Suppression of Large-scale Flow and Heat Transfer Enhancement; 2.8.5 Prandtl Number Effects; Chapter 3 Spherical Shells, Rossby Waves and Centrifugally Driven Thermal Convection; 3.1 The Coriolis Effect in Atmosphere Dynamics 3.1.1 The Origin of the Zonal Winds |
| Record Nr. | UNINA-9910818161403321 |
|
Lappa Marcello
|
||
| Hoboken, N.J., : Wiley, 2012 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Thermal convection [[electronic resource] ] : patterns, evolution, and stability (historical background and current status) / / Marcello Lappa
| Thermal convection [[electronic resource] ] : patterns, evolution, and stability (historical background and current status) / / Marcello Lappa |
| Autore | Lappa Marcello |
| Pubbl/distr/stampa | Hoboken, N.J., : Wiley, 2009 |
| Descrizione fisica | 1 online resource (692 p.) |
| Disciplina |
541.36
620.11296 |
| Soggetto topico |
Thermal conductivity
Density currents Viscous flow Fluid dynamics |
| ISBN |
1-282-37960-7
9786612379604 0-470-74998-9 0-470-74999-7 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Thermal Convection; Contents; Preface; Acknowledgements; 1 Equations, General Concepts and Methods of Analysis; 1.1 Pattern Formation and Nonlinear Dynamics; 1.1.1 Some Fundamental Concepts: Pattern, Interrelation and Scale; 1.1.2 PDEs, Symmetry and Nonequilibrium Phenomena; 1.2 The Navier-Stokes Equations; 1.2.1 A Satisfying Microscopic Derivation of the Balance Equations; 1.2.2 A Statistical Mechanical Theory of Transport Processes; 1.2.3 The Continuity Equation; 1.2.4 The Momentum Equation; 1.2.5 The Total Energy Equation; 1.2.6 The Budget of Internal Energy; 1.2.7 Newtonian Fluids
1.2.8 Some Considerations About the Dynamics of Vorticity1.2.9 Incompressible Formulation of the Balance Equations; 1.2.10 Nondimensional Form of the Equations for Thermal Problems; 1.3 Energy Equality and Dissipative Structures; 1.4 Flow Stability, Bifurcations and Transition to Chaos; 1.5 Linear Stability Analysis: Principles and Methods; 1.5.1 Conditional Stability and Infinitesimal Disturbances; 1.5.2 The Exponential Matrix and the Eigenvalue Problem; 1.5.3 Linearization of the Navier-Stokes Equations 1.5.4 A Simple Example: The Stability of a Parallel Flow with an Inflectional Velocity Profile1.5.5 Weaknesses and Limits of the Linear Stability Approach; 1.6 Energy Stability Theory; 1.6.1 A Global Budget for the Generalized Disturbance Energy; 1.6.2 The Extremum Problem; 1.7 Numerical Integration of the Navier-Stokes Equations; 1.7.1 Vorticity Methods; 1.7.2 Primitive Variables Methods; 1.8 Some Universal Properties of Chaotic States; 1.8.1 Feigenbaum, Ruelle-Takens and Manneville-Pomeau Scenarios; 1.8.2 Phase Trajectories, Attractors and Strange Attractors 1.8.3 The Lorenz Model and the Butterfly Effect1.8.4 A Possible Quantification of SIC: The Lyapunov Spectrum; 1.8.5 The Mandelbrot Set: The Ubiquitous Connection Between Chaos and Fractals; 1.9 The Maxwell Equations; 2 Classical Models, Characteristic Numbers and Scaling Arguments; 2.1 Buoyancy Convection and the Boussinesq Model; 2.2 Convection in Space; 2.2.1 A Definition of Microgravity; 2.2.2 Experiments in Space; 2.2.3 Surface Tension-driven Flows; 2.2.4 Acceleration Disturbances on Orbiting Platforms and Vibrational Flows; 2.3 Marangoni Flow 2.3.1 The Genesis and Relevant Nondimensional Numbers2.3.2 Microzone Facilities and Microscale Experimentation; 2.3.3 A Paradigm Model: The Liquid Bridge; 2.4 Exact Solutions of the Navier-Stokes Equations for Thermal Problems; 2.4.1 Thermogravitational Convection: The Hadley Flow; 2.4.2 Marangoni Flow; 2.4.3 Hybrid States; 2.4.4 General Properties; 2.4.5 The Infinitely Long Liquid Bridge; 2.4.6 Inclined Systems; 2.5 Conductive, Transition and Boundary-layer Regimes; 3 Examples of Thermal Fluid Convection and Pattern Formation in Nature and Technology 3.1 Technological Processes: Small-scale Laboratory and Industrial Setups |
| Record Nr. | UNINA-9910139959803321 |
|
Lappa Marcello
|
||
| Hoboken, N.J., : Wiley, 2009 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Thermal convection [[electronic resource] ] : patterns, evolution, and stability (historical background and current status) / / Marcello Lappa
| Thermal convection [[electronic resource] ] : patterns, evolution, and stability (historical background and current status) / / Marcello Lappa |
| Autore | Lappa Marcello |
| Pubbl/distr/stampa | Hoboken, N.J., : Wiley, 2009 |
| Descrizione fisica | 1 online resource (692 p.) |
| Disciplina |
541.36
620.11296 |
| Soggetto topico |
Thermal conductivity
Density currents Viscous flow Fluid dynamics |
| ISBN |
1-282-37960-7
9786612379604 0-470-74998-9 0-470-74999-7 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Thermal Convection; Contents; Preface; Acknowledgements; 1 Equations, General Concepts and Methods of Analysis; 1.1 Pattern Formation and Nonlinear Dynamics; 1.1.1 Some Fundamental Concepts: Pattern, Interrelation and Scale; 1.1.2 PDEs, Symmetry and Nonequilibrium Phenomena; 1.2 The Navier-Stokes Equations; 1.2.1 A Satisfying Microscopic Derivation of the Balance Equations; 1.2.2 A Statistical Mechanical Theory of Transport Processes; 1.2.3 The Continuity Equation; 1.2.4 The Momentum Equation; 1.2.5 The Total Energy Equation; 1.2.6 The Budget of Internal Energy; 1.2.7 Newtonian Fluids
1.2.8 Some Considerations About the Dynamics of Vorticity1.2.9 Incompressible Formulation of the Balance Equations; 1.2.10 Nondimensional Form of the Equations for Thermal Problems; 1.3 Energy Equality and Dissipative Structures; 1.4 Flow Stability, Bifurcations and Transition to Chaos; 1.5 Linear Stability Analysis: Principles and Methods; 1.5.1 Conditional Stability and Infinitesimal Disturbances; 1.5.2 The Exponential Matrix and the Eigenvalue Problem; 1.5.3 Linearization of the Navier-Stokes Equations 1.5.4 A Simple Example: The Stability of a Parallel Flow with an Inflectional Velocity Profile1.5.5 Weaknesses and Limits of the Linear Stability Approach; 1.6 Energy Stability Theory; 1.6.1 A Global Budget for the Generalized Disturbance Energy; 1.6.2 The Extremum Problem; 1.7 Numerical Integration of the Navier-Stokes Equations; 1.7.1 Vorticity Methods; 1.7.2 Primitive Variables Methods; 1.8 Some Universal Properties of Chaotic States; 1.8.1 Feigenbaum, Ruelle-Takens and Manneville-Pomeau Scenarios; 1.8.2 Phase Trajectories, Attractors and Strange Attractors 1.8.3 The Lorenz Model and the Butterfly Effect1.8.4 A Possible Quantification of SIC: The Lyapunov Spectrum; 1.8.5 The Mandelbrot Set: The Ubiquitous Connection Between Chaos and Fractals; 1.9 The Maxwell Equations; 2 Classical Models, Characteristic Numbers and Scaling Arguments; 2.1 Buoyancy Convection and the Boussinesq Model; 2.2 Convection in Space; 2.2.1 A Definition of Microgravity; 2.2.2 Experiments in Space; 2.2.3 Surface Tension-driven Flows; 2.2.4 Acceleration Disturbances on Orbiting Platforms and Vibrational Flows; 2.3 Marangoni Flow 2.3.1 The Genesis and Relevant Nondimensional Numbers2.3.2 Microzone Facilities and Microscale Experimentation; 2.3.3 A Paradigm Model: The Liquid Bridge; 2.4 Exact Solutions of the Navier-Stokes Equations for Thermal Problems; 2.4.1 Thermogravitational Convection: The Hadley Flow; 2.4.2 Marangoni Flow; 2.4.3 Hybrid States; 2.4.4 General Properties; 2.4.5 The Infinitely Long Liquid Bridge; 2.4.6 Inclined Systems; 2.5 Conductive, Transition and Boundary-layer Regimes; 3 Examples of Thermal Fluid Convection and Pattern Formation in Nature and Technology 3.1 Technological Processes: Small-scale Laboratory and Industrial Setups |
| Record Nr. | UNINA-9910829961403321 |
|
Lappa Marcello
|
||
| Hoboken, N.J., : Wiley, 2009 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Thermal convection : patterns, evolution, and stability (historical background and current status) / / Marcello Lappa
| Thermal convection : patterns, evolution, and stability (historical background and current status) / / Marcello Lappa |
| Autore | Lappa Marcello |
| Pubbl/distr/stampa | Hoboken, N.J., : Wiley, 2009 |
| Descrizione fisica | 1 online resource (692 p.) |
| Disciplina | 620.1/1296 |
| Soggetto topico |
Thermal conductivity
Density currents Viscous flow Fluid dynamics |
| ISBN |
1-282-37960-7
9786612379604 0-470-74998-9 0-470-74999-7 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Thermal Convection; Contents; Preface; Acknowledgements; 1 Equations, General Concepts and Methods of Analysis; 1.1 Pattern Formation and Nonlinear Dynamics; 1.1.1 Some Fundamental Concepts: Pattern, Interrelation and Scale; 1.1.2 PDEs, Symmetry and Nonequilibrium Phenomena; 1.2 The Navier-Stokes Equations; 1.2.1 A Satisfying Microscopic Derivation of the Balance Equations; 1.2.2 A Statistical Mechanical Theory of Transport Processes; 1.2.3 The Continuity Equation; 1.2.4 The Momentum Equation; 1.2.5 The Total Energy Equation; 1.2.6 The Budget of Internal Energy; 1.2.7 Newtonian Fluids
1.2.8 Some Considerations About the Dynamics of Vorticity1.2.9 Incompressible Formulation of the Balance Equations; 1.2.10 Nondimensional Form of the Equations for Thermal Problems; 1.3 Energy Equality and Dissipative Structures; 1.4 Flow Stability, Bifurcations and Transition to Chaos; 1.5 Linear Stability Analysis: Principles and Methods; 1.5.1 Conditional Stability and Infinitesimal Disturbances; 1.5.2 The Exponential Matrix and the Eigenvalue Problem; 1.5.3 Linearization of the Navier-Stokes Equations 1.5.4 A Simple Example: The Stability of a Parallel Flow with an Inflectional Velocity Profile1.5.5 Weaknesses and Limits of the Linear Stability Approach; 1.6 Energy Stability Theory; 1.6.1 A Global Budget for the Generalized Disturbance Energy; 1.6.2 The Extremum Problem; 1.7 Numerical Integration of the Navier-Stokes Equations; 1.7.1 Vorticity Methods; 1.7.2 Primitive Variables Methods; 1.8 Some Universal Properties of Chaotic States; 1.8.1 Feigenbaum, Ruelle-Takens and Manneville-Pomeau Scenarios; 1.8.2 Phase Trajectories, Attractors and Strange Attractors 1.8.3 The Lorenz Model and the Butterfly Effect1.8.4 A Possible Quantification of SIC: The Lyapunov Spectrum; 1.8.5 The Mandelbrot Set: The Ubiquitous Connection Between Chaos and Fractals; 1.9 The Maxwell Equations; 2 Classical Models, Characteristic Numbers and Scaling Arguments; 2.1 Buoyancy Convection and the Boussinesq Model; 2.2 Convection in Space; 2.2.1 A Definition of Microgravity; 2.2.2 Experiments in Space; 2.2.3 Surface Tension-driven Flows; 2.2.4 Acceleration Disturbances on Orbiting Platforms and Vibrational Flows; 2.3 Marangoni Flow 2.3.1 The Genesis and Relevant Nondimensional Numbers2.3.2 Microzone Facilities and Microscale Experimentation; 2.3.3 A Paradigm Model: The Liquid Bridge; 2.4 Exact Solutions of the Navier-Stokes Equations for Thermal Problems; 2.4.1 Thermogravitational Convection: The Hadley Flow; 2.4.2 Marangoni Flow; 2.4.3 Hybrid States; 2.4.4 General Properties; 2.4.5 The Infinitely Long Liquid Bridge; 2.4.6 Inclined Systems; 2.5 Conductive, Transition and Boundary-layer Regimes; 3 Examples of Thermal Fluid Convection and Pattern Formation in Nature and Technology 3.1 Technological Processes: Small-scale Laboratory and Industrial Setups |
| Record Nr. | UNINA-9910876535003321 |
|
Lappa Marcello
|
||
| Hoboken, N.J., : Wiley, 2009 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Thermal Flows
| Thermal Flows |
| Autore | Lappa Marcello |
| Pubbl/distr/stampa | Basel, : MDPI - Multidisciplinary Digital Publishing Institute, 2022 |
| Descrizione fisica | 1 electronic resource (232 p.) |
| Soggetto topico |
Research & information: general
Physics |
| Soggetto non controllato |
coating flow
free surface boundary layer stress singularity matched asymptotic expansions computational fluid dynamics turbulence rotating thermal convection Rayleigh-Bénard heat enhancement nanofluid circular pipe twisted tape porous media metal foam convection-driven dynamos numerical simulations bistability mean-field magnetohydrodynamics spherical shells stochastic equations equivalence of measures nature of turbulence critical Reynolds number thermovibrational convection gravity modulation thermofluid-dynamic distortions patterning behavior stratified mixing layer non-modal instability Kelvin-Helmholtz instability Holmboe instability rotating thermal magnetoconvection linear onset sphere Rayleigh-Bénard convection time periodical cooling Lattice Boltzmann method thermocapillary-driven convection half-zone liquid bridges particles coherent structures particle accumulation structure (PAS) high Prandtl number fluids plane layer circular translational vibrations thermal vibrational convection convective patterns |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910566480903321 |
|
Lappa Marcello
|
||
| Basel, : MDPI - Multidisciplinary Digital Publishing Institute, 2022 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||