HYDRODYNAMICS – ADVANCED TOPICS Edited by Harry Edmar Schulz, André Luiz Andrade Simões and Raquel Jahara Lobosco Hydrodynamics – Advanced Topics Edited by Harry Edmar Schulz, André Luiz Andrade Simões and Raquel Jahara Lobosco Published by InTech Janeza Trdine 9, 51000 Rijeka, Croatia Copyright © 2011 InTech All chapters are Open Access distributed under the Creative Commons Attribution 3.0 license, which allows users to download, copy and build upon published articles even for commercial purposes, as long as the author and publisher are properly credited, which ensures maximum dissemination and a wider impact of our publications. After this work has been published by InTech, authors have the right to republish it, in whole or part, in any publication of which they are the author, and to make other personal use of the work. Any republication, referencing or personal use of the work must explicitly identify the original source. 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First published December, 2011 Printed in Croatia A free online edition of this book is available at www.intechopen.com Additional hard copies can be obtained from orders@intechweb.org Hydrodynamics – Advanced Topics, Edited by Harry Edmar Schulz, André Luiz Andrade Simões and Raquel Jahara Lobosco p. cm. ISBN 978-953-307-596-9 free online editions of InTech Books and Journals can be found at www.intechopen.com Contents Preface IX Part 1 Mathematical Models in Fluid Mechanics 1 Chapter 1 One Dimensional Turbulent Transfer Using Random Square Waves – Scalar/Velocity and Velocity/Velocity Interactions 3 H. E. Schulz, G. B. Lopes Júnior, A. L. A. Simões and R. J. Lobosco Chapter 2 Generalized Variational Principle for Dissipative Hydrodynamics: Shear Viscosity from Angular Momentum Relaxation in the Hydrodynamical Description of Continuum Mechanics 35 German A. Maximov Chapter 3 Nonautonomous Solitons: Applications from Nonlinear Optics to BEC and Hydrodynamics 51 T. L. Belyaeva and V. N. Serkin Chapter 4 Planar Stokes Flows with Free Boundary 77 Sergey Chivilikhin and Alexey Amosov Part 2 Biological Applications and Biohydrodynamics 93 Chapter 5 Laser-Induced Hydrodynamics in Water and Biotissues Nearby Optical Fiber Tip 95 V. I. Yusupov, V. M. Chudnovskii and V. N. Bagratashvili Chapter 6 Endocrine Delivery System of NK4, an HGF-Antagonist and Anti-Angiogenic Regulator, for Inhibitions of Tumor Growth, Invasion and Metastasis 119 Shinya Mizuno and Toshikazu Nakamura VI Contents Part 3 Detailed Experimental Analyses of Fluids and Flows 143 Chapter 7 Microrheology of Complex Fluids 145 Laura J. Bonales, Armando Maestro, Ramón G. Rubio and Francisco Ortega Chapter 8 Hydrodynamics Influence on Particles Formation Using SAS Process 169 A. Montes, A. Tenorio, M. D. Gordillo, C. Pereyra and E. J. Martinez de la Ossa Chapter 9 Rotational Dynamics of Nonpolar and Dipolar Molecules in Polar and Binary Solvent Mixtures 185 Sanjeev R. Inamdar Chapter 10 Flow Instabilities in Mechanically Agitated Stirred Vessels 227 Chiara Galletti and Elisabetta Brunazzi Chapter 11 Hydrodynamic Properties of Aggregates with Complex Structure 251 Lech Gmachowski Part 4 Radiation-, Electro-, Magnetohydrodynamics and Magnetorheology 267 Chapter 12 Electro-Hydrodynamics of Micro-Discharges in Gases at Atmospheric Pressure 269 O. Eichwald, M. Yousfi, O. Ducasse, N. Merbahi, J.P. Sarrette, M. Meziane and M. Benhenni Chapter 13 An IMEX Method for the Euler Equations that Posses Strong Non-Linear Heat Conduction and Stiff Source Terms (Radiation Hydrodynamics) 293 Samet Y. Kadioglu and Dana A. Knoll Chapter 14 Hydrodynamics on Charged Superparamagnetic Microparticles in Water Suspension: Effects of Low-Confinement Conditions and Electrostatics Interactions 319 P. Domínguez-García and M.A. Rubio Chapter 15 Magnetohydrodynamics of Metallic Foil Electrical Explosion and Magnetically Driven Quasi-Isentropic Compression 347 Guiji Wang, Jianheng Zhao, Binqiang Luo and Jihao Jiang Contents VII Part 5 Special Topics on Simulations and Experimental Data 379 Chapter 16 Hydrodynamics of a Droplet in Space 381 Hitoshi Miura Chapter 17 Flow Evolution Mechanisms of Lid-Driven Cavities 411 José Rafael Toro and Sergio Pedraza R. Chapter 18 Elasto-Hydrodynamics of Quasicrystals and Its Applications 429 Tian You Fan and Zhi Yi Tang Preface “Water is the beginning of everything” (Tales of Mile to) “Air is the beginning of everything” (Anaxagoras of Mile to) Introduction Why is it important to study Hydrodynamics? The answer may be strictly technical, but it may also involve some kind of human feeling about our environment and our (eventual) limitations to deal with its fluidic constituents. As teachers, when talking to our students about the importance of quantifying fluids, we (authors) go to the blackboard and draw, in blue color, a small circumference in the center of the board, and add the obvious name 'Earth'. Some words are then said, in the sense that Hydrodynamics is important, because we are beings strictly adapted to live immersed in a fluidic environment (air), and because we are beings composed basically by simple fluidic solutions (water solutions), encapsulated in fine carbon membranes. Then, with a red chalk, we draw two crosses: one inside and the other outside the circumference, explaining: “our environment is very limited. We can only survive in the space covered by the blue line. No one of us can survive in the inner part of this sphere, or in the outer space. Despite all films, games, and books about contacts with aliens, and endless journeys across the universe, our present knowledge only allows to suggest that it is most probable that the human being will extinct while in this fine fluid membrane, than to create sustainable artificial environments in the cosmos”. Sometimes, to add some drama, we project the known image of the earth on a wall (the image of the blue sphere), and then we blow a soap bubble explaining that the image gives the false impression that the entire sphere is our home. But our “home” is better represented by the liquid film of the soap bubble (only the film) and then we touch the bubble, exploding it, showing its fragility. In the sequence, we explain that a first reason to understand fluids would be, then, to guarantee the maintenance of the fluidic environment (the film) so that we could also guarantee our survival as much as possible. Further, as we move ourselves and produce our things immersed in fluid, it is interesting to optimize such operations in order to facilitate our survival. Still further, because our organisms interchange heat X Preface and mass in cellular and corporal scales between different fluids, the understanding of these transports permits us to understand the spreading of diseases, the delivering of medicines to cells, and the use of physical properties of fluids in internal treatments. Thus, understanding these transports allows us to improve our quality of life. Finally, the observation of the inner part of the sphere, the outer space and its constituents, shows that many “highly energetic” phenomena behave like the fluids around us. It gives us the hope that the knowledge of fluids can help, in the future, to quantify, reproduce, control and use energy sources similar to those of the stars, allowing us to “move through the cosmos”, to create sustainable artificial environments and to leave this “limited film” when necessary. Of course, this “speech” may be viewed as a sort of escapism, related to a fiction of the future. In fact, the day-by-day activities show that we are spending our time with “more important” things, like fighting among us for the dividends of the next fashion wave (or the next technical wave), the hierarchy among nations, or the hierarchy of the cultures of the different nations. So, fighters, warriors, or generals still seem to be the agents that write our history. But global survival, or, in other words, the guarantee of any future history, will need other agents, devoted to other activities. The hope lies on the generation of knowledge, in which the knowledge about fluids is vital. Context of the present book “Hydrodynamics - Advanced Topics” A quick search in virtual book stores may result in more than one hundred titles involving the word “Hydrodynamics”. Considering the superposition existing with Fluid Mechanics, the number of titles grows much more. Considering all these titles, why try to organize another book on Hydrodynamics? One answer could be that the researchers always try new points of view to understand and treat the problems related to Hydrodynamics. Even a much known phenomenon may be re-explained from a point of view that introduces different tools (conceptual, numerical or practical) into the discussion of fluids. And eventually, a detail shows to be useful, or even very relevant. So, it is necessary to give the opportunity for the different authors to expose their points of view. Among the historically relevant books on Hydrodynamics, some should be mentioned here. For example, the volumes “Hydrodynamics” and “Hydraulics”, by Daniel Bernoulli (1738) and his father, Johann Bernoulli (1743) present many interesting sketches and the analyses that converged to the so called “Bernoulli equation”, later deduced more properly by Leonhard Euler. Although there are unpleasant questions about the authorship of the main ideas, as pointed out by Rouse (1967) and Calero (2008), both books are placed in a “prominent position” in history, because of their significant contributions. The volume written by Sir Horace Lamb (1879), now named “Hydrodynamics”, considers the basic equations, the vortex motion, and tidal waves, among other interesting topics. Considering the classical equations and procedures followed to study fluid motion, the books “Fundamentals of Hydro and Aerodynamics“ and “Applied Hydro and Aerodynamics“ by Prandtl and Tietjens (1934) present the theory and its practical applications in a comprehensive way, [...]... working with Hydrodynamics The book Hydrodynamics - Advanced Topics is organized in the following manner: Part 1: Mathematical Models in Fluid Mechanics Part 2: Biological Applications and Biohydrodynamics Part 3: Detailed Experimental Analyses of Fluids and Flows Part 4: Radiation-, Electro-, Magnetohydrodynamics and Magnetorheology Part 5: Special Topics on Simulations and Experimental Data Hydrodynamics. .. general central moments ( =1, 2, 3…) for the scalar fluctuation f are given by f   1  f 1 n  f 2  1  n   n  1  n   1  n   or, normalizing the th f '    1    1   n    Fp  Fn   1   f    (24) root ( )  f   Fp  Fn   1   n  1  n   1  n     1    1   n   1   f  (25) The functional form of the statistical quantities shown here must be obtained... New York, 19 68 (first publication) and reissued in 2005, ISBN -10 : 04864 418 57 Hydraulica, by Johann Bernoulli, as published by Marc-Michel Bousquet et Cie at Lausanne and Geneva in 17 43 Calero, J.S (2008), The genesis of fluid mechanics (16 40 -17 80) Springer, ISBN 978 -14 020-6 413 -5 Original title: La génesis de la Mecánica de los Fluidos (16 40– 17 80), UNED, Madrid, 19 96 Chandrasekhar, S (19 61) , Hydrodynamic... F  F       1, 2, 3, ( 21) For any statistical phenomenon, the first order central moment ( =1) is always zero Using equations (14 ) and (15 ), Schulz & Janzen (2009) showed that the second order central moment ( f 2 for =2) is given by f 2   f 12 n  f 2 2  1  n   n  1  n  1   f or, normalizing the RMS value (f ’2)   Fp  Fn  2 2 (22) 14 Hydrodynamics – Advanced Topics f '2  f 2... Applied Mathematics series 19 53 Reissued in the Cambridge Science Classics series 19 82 (ISBN: 0 5 21 0 411 7 1) Bernoulli, D (17 38), Hydrodynamics Dover Publications, Inc., Mineola, New York, 19 68 (first publication) and reissued in 2005, ISBN -10 : 04864 418 57 Preface Hydrodynamica, by Daniel Bernoulli, as published by Johann Reinhold Dulsecker at Strassburg in 17 38 Bernoulli, J (17 43), Hydraulics Dover Publications,... u  1  m  (16 ) Equation (17 ) describes the zero mean velocity (remembering that  d m  u  1  m   0 or U U  0 U is a function of z Let us now consider the RMS velocity 2  2  m d   1  m   u  U and 2 and is negative) (17 )  2 , which is calculated as 2  2  m d   1  m   u  2 (18 )  2 may be easily related From equations (13 ), (16 ), and (18 ) it follows that U   2 1  ... (19 61) , Hydrodynamic and Hydromagnetic Stability Clarendon Press edition, 19 61 Dover edition, first published in 19 81 (ISBN: 0-486-64071X) Drazin, P.G & Reid, W.H (19 81) , Hydrodynamic stability Cambridge University Press (second edition 2004) (ISBN: 0 5 21 525 41 1) Hinze, J.O (19 59), Turbulence McGraw-Hill, Inc second edition, 19 75 (ISBN:0-07029037-7) Kundu, P.K & Cohen, I.M (2008), Fluid Mechanics 4th... through 2.5 (partition, reduction and superposition functions) are also used, and they must “adjust” the statistical quantities to adequate values From equations (8), (10 ), and (11 ), the two instantaneous scalar fluctuations are then given by equations (14 ) and (15 )     f 1  Fp  P  F  (1  n) Fp  Fn 1   f   f 2   Fn  N  F   n Fp  Fn 1   f   (positive) (negative) (14 ) (15 ) 2.7... mass-transfer, which showed values close to 1 in both the vicinity of the surface and in the bulk liquid, and closer to 0 in an intermediate region (giving therefore a minimum value in this region) 10 Hydrodynamics – Advanced Topics From equations (7), (8) and (10 ), N and P are now expressed as      P   f  1  n  Fp  Fn   N   f n Fp  Fn   0 f  1 (11 ) As for the partition functions, any new variable... Publications, Inc Ed 19 57 Schlichting, H (19 51) , Grenzschicht-Theorie Karlsruhe: Verlag und Druck Stoker, J.J (19 57) Water waves: the mathematical theory with applications Interscience Publishers, New York (ISBN -10 : 04 715 70346) Part 1 Mathematical Models in Fluid Mechanics 1 One Dimensional Turbulent Transfer Using Random Square Waves – Scalar/Velocity and Velocity/Velocity Interactions H E Schulz1,2, G B Lopes . Mathematics series 19 53. Reissued in the Cambridge Science Classics series 19 82 (ISBN: 0 5 21 0 411 7 1) . Bernoulli, D. (17 38), Hydrodynamics. Dover Publications, Inc., Mineola, New York, 19 68 (first. fluid mechanics (16 40 -17 80). Springer, ISBN 978 -1- 4020-6 413 -5. Original title: La génesis de la Mecánica de los Fluidos (16 40– 17 80), UNED, Madrid, 19 96. Chandrasekhar, S. (19 61) , Hydrodynamic. with Hydrodynamics. The book Hydrodynamics - Advanced Topics is organized in the following manner: Part 1: Mathematical Models in Fluid Mechanics Part 2: Biological Applications and Biohydrodynamics