05249nam 2200685 a 450 991081816140332120240516205347.01-283-64505-X1-118-34238-01-118-34240-21-118-34241-0(CKB)2550000000108192(EBL)978376(OCoLC)780415805(SSID)ssj0000715379(PQKBManifestationID)11472755(PQKBTitleCode)TC0000715379(PQKBWorkID)10703480(PQKB)11128875(MiAaPQ)EBC978376(DLC) 2012011416(Au-PeEL)EBL978376(CaPaEBR)ebr10582603(CaONFJC)MIL395755(PPN)165706724(EXLCZ)99255000000010819220120229d2012 uy 0engurcn|||||||||txtccrRotating thermal flows in natural and industrial processes[electronic resource] /Marcello Lappa1st ed.Hoboken, N.J. Wiley20121 online resource (542 p.)Description based upon print version of record.1-119-96079-7 Includes bibliographical references and index.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 Convection1.4.1 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 Rotation1.7.1 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 Instability2.5 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 Bifurcations2.7 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 Dynamics3.1.1 The Origin of the Zonal Winds"In this context, it is expressly shown how the aforementioned isomorphism between small and large scale phenomena becomes beneficial to the definition and ensuing development of an integrated comprehensive framework allowing the reader to understand and assimilate the underlying quintessential mechanisms without requiring, however, familiarity with specific literature on the subject"--Provided by publisher.HeatTransmissionRotating masses of fluidHeatTransmission.Rotating masses of fluid.536/.2SCI065000bisacshLappa Marcello964709MiAaPQMiAaPQMiAaPQBOOK9910818161403321Rotating thermal flows in natural and industrial processes3956150UNINA