05581nam 2200793Ia 450 991082743330332120200520144314.09781118795613111879561X9781118795620111879562897811187956371118795636(CKB)2670000000402161(EBL)1332528(SSID)ssj0001034946(PQKBManifestationID)11677469(PQKBTitleCode)TC0001034946(PQKBWorkID)11016386(PQKB)11003280(Au-PeEL)EBL1332528(CaPaEBR)ebr10740439(CaONFJC)MIL508840(MiAaPQ)EBC1332528(OCoLC)855504057(Perlego)1002444(EXLCZ)99267000000040216120130812d2013 uy 0engur|n|---|||||txtccrAdvances in contact angle, wettability and adhesionVolume 1 /edited by K. L. Mittal1st ed.Salem, Mass. Scrivener/Wileyc20131 online resource (436 p.)Adhesion and adhesives : fundamental and applied aspectsDescription based upon print version of record.9781299775893 1299775896 9781118472927 1118472926 Includes bibliographical references.Cover; Title Page; Copyright Page; Contents; Preface; Acknowledgements; Part 1: Fundamental Aspects; 1 Correlation between Contact Line Pinning and Contact Angle Hysteresis on Heterogeneous Surfaces: A Review and Discussion; 1.1 Introduction; 1.2 Contact Line Pinning on Chemically Heterogeneous Flat Surfaces; 1.3 Contact Line Pinning on Hydrophobic Structured Surfaces; 1.4 Summary and Conclusion; References; 2 Computational and Experimental Study of Contact Angle Hysteresis in Multiphase Systems; 2.1 Introduction; 2.2 Origins of the CA Hysteresis2.3 Modeling Wetting/Dewetting in Multiphase Systems2.3.1 CA in Multiphase Systems; 2.3.2 CA Hysteresis in Multiphase Systems; 2.4 Experimental Observations; 2.5 Numerical Modeling of CA Hysteresis; 2.5.1 Background; 2.5.2 The Cellular Potts Model; 2.5.3 The Cellular Potts Modeling of Wetting; 2.5.4 Results; 2.6 Conclusions; Acknowledgement; References; 3 Heterogeneous Nucleation on a Completely Wettable Substrate; 3.1 Introduction; 3.2 Interface-Displacement Model; 3.3 Nucleation on a Completely-Wettable Flat Substrate; 3.3.1 d = 2-dimensional Nucleus; 3.3.2 d = 3-dimensional Nucleus3.4 Nucleation on a Completely-Wettable Spherical Substrate3.5 Conclusion; Acknowledgments; References; 4 Local Wetting at Contact Line on Textured Hydrophobic Surfaces; 4.1 Introduction; 4.2 Static Contact Angle; 4.2.1 Global Approach - Thermodynamic Equilibrium; 4.2.2 Local Approach - Force Balance; 4.3 Wetting of Single Texture Element; 4.4 Summary; References; 5 Fundamental Understanding of Drops Wettability Behavior Theoretically and Experimentally; 5.1 Introduction; 5.2 Discussion; 5.3 Conclusion; References6 Hierarchical Structures Obtained by Breath Figures Self-Assembly and Chemical Etching and their Wetting Properties6.1 Introduction; 6.2 Materials and Methods; 6.2.1 Fabricating Hierarchical Polymer Surfaces; 6.2.2 Characterization of the Wetting Properties of Polymer Surfaces; 6.2.3 Plasma Treatment of the Surfaces; 6.2.4 B.E.T Characterization of the Surfaces; 6.3 Results and Discussion; 6.3.1 Morphology and Wetting Properties of the Multi-scaled PC Surfaces; 6.3.2 Modification of Wetting Properties of the Multi-scaled Surfaces with Cold Radiofrequency Plasma Treatment6.3.3 B.E.T Study of the Surfaces6.4 Conclusions; Acknowledgements; References; 7 Computational Aspects of Self-Cleaning Surface Mechanisms; 7.1 Introduction; 7.2 Droplet Membrane; 7.2.1 Governing Equations in Strong Form; 7.2.1.1 Surface Contact; 7.2.1.2 Line Contact; 7.2.1.3 Surface Roughness; 7.2.2 Weak Formulation of the Governing Equations; 7.2.2.1 Finite Element Implementation; 7.2.3 Model Verification; 7.2.3.1 Force Equilibrium; 7.2.4 Particle-Droplet Interaction; 7.3 Flow Model; 7.3.1 Governing Equations; 7.3.2 Finite Element Implementation7.3.3 Normal and Tangential Velocities at the BoundaryThe topic of wettabilty is extremely important from both fundamental and applied aspects. The applications of wettability range from self-cleaning windows to micro- and nanofluidics. This book represents the cumulative wisdom of a contingent of world-class (researchers engaged in the domain of wettability. In the last few years there has been tremendous interest in the ""Lotus Leaf Effect"" and in understanding its mechanism and how to replicate this effect for myriad applications. The topics of superhydrophobicity, omniphobicity and superhydrophilicity are of much contemporary interest andAdhesion and adhesives.Surface chemistryContact angleWettingAdhesionSurface chemistry.Contact angle.Wetting.Adhesion.541/.33Mittal K. L.1945-748276MiAaPQMiAaPQMiAaPQBOOK9910827433303321Advances in contact angle, wettability and adhesion4113783UNINA02494oas 2201009 a 450 991014695710332120260203110245.01559-0089(DE-599)ZDB2099780-2(OCoLC)52860607(CONSER) 2005215862(CKB)111038336087000(DE-599)2099780-2(EXLCZ)9911103833608700020030818a20039999 sy aengurcnu||||||||txtrdacontentcrdamediacrrdacarrierNeuroinformaticsTotowa, NJ Humana Press©2003-[New York] Springer USRefereed/Peer-reviewed1539-2791 NeuroinformaticsNeuroinformaticsPeriodicalsNeurosciencesNeural Networks, ComputerModels, NeurologicalComputer SimulationNeuroinformaticsfast(OCoLC)fst01036362Informàtica mèdicathubNeurociènciesthubXarxes neuronals (Informàtica)thubSimulació per ordinadorthubPeriodicals.fastRevistes electròniques.thubNeuroinformaticsNeurosciences.Neural Networks, Computer.Models, Neurological.Computer Simulation.Neuroinformatics.Informàtica mèdica.Neurociències.Xarxes neuronals (Informàtica)Simulació per ordinador.616Humana PressOUNOUNOCLCQNSDOCLOCLCQVRCOCLCQOCLCFOCLCQZ5AOCLCOOCLCAREBOCLCOU3WOCLCOAU@OCLCOWYUOCLCOUKMGBNJTOCLCOVT2DLCOCLCAOCLCQUABQGKSFBOCLCLOCLCQJOURNAL9910146957103321Neuroinformatics1015076UNINA