Wave oscillations in colloid oxyhydrates /
The importance of coherent chemistry, that is, the chemistry of periodic oscillatory processes, is increasing at a rapid rate in specific chemical disciplines. While being perfectly understood and highly developed in the fields of physical chemistry, chemical physics and biological chemistry, the pe...
Clasificación: | Libro Electrónico |
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Autor principal: | |
Formato: | Electrónico eBook |
Idioma: | Inglés |
Publicado: |
Stafa-Zuerich, Switzerland ; Enfield, New Hampshire :
Trans Tech Publications,
[2010]
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Colección: | Materials science foundations ;
v. 70-71. |
Temas: | |
Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Wave Oscillations in Colloid Oxyhydrates; Preface; Table of Contents; Summary; Table of Contents; 1. Periodical Pulsation Ionic Flow Properties of Oxo-Olic Complexes of Zirconium and Silicium; 1.1 Polymerization of the Hydrated Particles of Zirconium Oxyhydrate; 1.2 Emission-Wave Duality of Behavior of the Periodical Processes in the D- and F-Elements' Oxyhydrates. 1.3 Periodicity of the Efficient Diffusion Coefficients; 1.4 Quantization of the Pacemakers' Radiuses in Oxyhydrate Gels; 1.5 Bifurcation of the Pacemakers' Radius Doubling in Gel Oxyhydrate Systems
- 1.6 Extensional Dilatancy and Dimensions of the Pacemakers1.7 The Periodical State Isotherm; Abstract 1.1; 1.8 other Forms and Types of Oscillatory Motions in Oxyhydrate Systems; Abstract 1.2. Instrumental Support; 2. Behavior of Zirconium Oxyhydrate Gels Affected by the Spontaneous Pulsating Electrical Currents; 2.1 Theory; 2.2 Synchronization of the Periodical Oxyhydrate Systems; 2.3 Mathematical Modeling Problem; 2.4 Connections between Certain Self-Organization Parameters; 2.5 Conclusions
- 3. Zirconium Oxyhydrate Gels with Specifically Repeated Pulsation Macromolecules' Organizations: the Experimental Aspect3.1 Some of the TGM's Experimental Results; 3.2 Oxyhydrate Clusters Structuring in Non-Equilibrium Conditions; 3.3 the Way the Ageing Time Affects the Sorption Properties of the Zirconium Oxyhydrate; 3.4 Conclusions; 4. Modeling of the Oxyhydrate Gels' Shaping in an Active Excitable Medium. the Phase Transition Operator in Gels' Oxyhydrates (the Liesegang Operator)
- 4.1 Modeling of Autowave Shaping Processes in D- and F- Elements' Oxyhydrate Gels. the Simplest Mathematical Model of the Reaction-Diffusion Type4.2 Studies of a Modeled Oxyhydrate System; 4.3 Modeling of the Gel Shaping in an Active Excitable Medium by Means of the Molecular Dynamics Methods and the Monte Carlo Method; 4.4 Coulomb Diffusion Model; 5. Liesegang Operator; 4.5 Conclusions; 5.1 Liesegang Operator as a Reflection of the Gel Polymer Systems' Oscillatory Properties. Introduction of the Liesegang Operator; 5.2 Studying a Highly Nonlinear Diffusion Equation; Abstract 5.1 Theorems
- Abstract 5.2 Gel's Formation Stationary Problem5.3 Simplified Notation for the Liesegang Operator; 5.4 Hydrodynamic Approach; 5.5 Liesegang Operator and some Experimental Data; 5.6 Conclusions; 6. Liesegang Operator as a Consequence of the Ionic Molecular Motion inside the Lenard-Jones Potential; 6.1 Single-Particle Problem. Cluster's Motion in the Field of the Lenard-Jones Potential; 6.2 Cluster Motion in the Lenard-Jones Potential; 6.3 Experimental Detection of the Current Surges' Periodical Toroid Conformations in the Gel Oxyhydrate Systems, the Structural Self-Organization Stages