Volume is indexed by Thomson Reuters BCI (WoS).
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 periodic developmental paradigm of processes and phenomena still remains poorly developed and misunderstood in classical inorganic chemistry and related branches, such as colloid chemistry. The probability is that we miss subtle colloid chemical phenomena that could be of utmost importance if taken into consideration when catalysis or adsorption is involved. The author here reveals all of the astonishing vistas that periodic wave paradigms open up to researchers in certain colloid chemical systems, and will doubtless stimulate researchers to look at them in a new light.
Volume is indexed by Thomson Reuters BCI (WoS).
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 periodic developmental paradigm of processes and phenomena still remains poorly developed and misunderstood in classical inorganic chemistry and related branches, such as colloid chemistry. The probability is that we miss subtle colloid chemical phenomena that could be of utmost importance if taken into consideration when catalysis or adsorption is involved. The author here reveals all of the astonishing vistas that periodic wave paradigms open up to researchers in certain colloid chemical systems, and will doubtless stimulate researchers to look at them in a new light.
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Illustrations, unspecified
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ISBN-13
978-3-03813-447-3 (9783038134473)
DOI
10.4028/www.scientific.net/MSFo.70-71
Copyright in bibliographic data and cover images is held by Nielsen Book Services Limited or by the publishers or by their respective licensors: all rights reserved.
Schweitzer Klassifikation
<ul><li>Preface</li><li>Table of Contents</li><li>Summary</li><li>1. Periodical Pulsation Ionic Flow Properties of Oxo-Olic Complexes of Zirconium and Silicium</li><li>1.1 Polymerization of the Hydrated Particles of Zirconium Oxyhydrate</li><li>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</li><li>1.4 Quantization of the Pacemakers' Radiuses in Oxyhydrate Gels</li><li>1.5 Bifurcation of the Pacemakers' Radius Doubling in Gel Oxyhydrate Systems</li><li>1.6 Extensional Dilatancy and Dimensions of the Pacemakers</li><li>1.7 The Periodical State Isotherm</li><li>Abstract 1.1</li><li>1.8 other Forms and Types of Oscillatory Motions in Oxyhydrate Systems</li><li>Abstract 1.2. Instrumental Support</li><li>2. Behavior of Zirconium Oxyhydrate Gels Affected by the Spontaneous Pulsating Electrical Currents</li><li>2.1 Theory</li><li>2.2 Synchronization of the Periodical Oxyhydrate Systems</li><li>2.3 Mathematical Modeling Problem</li><li>2.4 Connections between Certain Self-Organization Parameters</li><li>2.5 Conclusions</li><li>3. Zirconium Oxyhydrate Gels with Specifically Repeated Pulsation Macromolecules' Organizations: the Experimental Aspect</li><li>3.1 Some of the TGM's Experimental Results</li><li>3.2 Oxyhydrate Clusters Structuring in Non-Equilibrium Conditions</li><li>3.3 the Way the Ageing Time Affects the Sorption Properties of the Zirconium Oxyhydrate</li><li>3.4 Conclusions</li><li>4. Modeling of the Oxyhydrate Gels' Shaping in an Active Excitable Medium. the Phase Transition Operator in Gels' Oxyhydrates (the Liesegang Operator)</li><li>4.1 Modeling of Autowave Shaping Processes in D- and F- Elements' Oxyhydrate Gels. the Simplest Mathematical Model of the Reaction-Diffusion Type</li><li>4.2 Studies of a Modeled Oxyhydrate System</li><li>4.3 Modeling of the Gel Shaping in an Active Excitable Medium by Means of the Molecular Dynamics Methods and the Monte Carlo Method</li><li>4.4 Coulomb Diffusion Model</li><li>5. Liesegang Operator</li><li>4.5 Conclusions</li><li>5.1 Liesegang Operator as a Reflection of the Gel Polymer Systems' Oscillatory Properties. Introduction of the Liesegang Operator</li><li>5.2 Studying a Highly Nonlinear Diffusion Equation</li><li>Abstract 5.1 Theorems</li><li>Abstract 5.2 Gel's Formation Stationary Problem</li><li>5.3 Simplified Notation for the Liesegang Operator</li><li>5.4 Hydrodynamic Approach</li><li>5.5 Liesegang Operator and some Experimental Data</li><li>5.6 Conclusions</li><li>6. Liesegang Operator as a Consequence of the Ionic Molecular Motion inside the Lenard-Jones Potential</li><li>6.1 Single-Particle Problem. Cluster's Motion in the Field of the Lenard-Jones Potential</li><li>6.2 Cluster Motion in the Lenard-Jones Potential</li><li>6.3 Experimental Detection of the Current Surges' Periodical Toroid Conformations in the Gel Oxyhydrate Systems, the Structural Self-Organization Stages</li><li>Abstract 6.1 Formative Characteristics of Zirconium Oxyhydrate Conformers</li><li>6.4 Colloid Chemical Version of the Arnold Diffusion in Oxyhydrate Systems</li><li>6.5 Conclusions</li><li>7. Organizational Mechanism in Colloid Chemical Stochastic Systems</li><li>7.1 Compiled Theoretical Consideration of the Synchronization Mechanism in Stochastic Systems as such</li><li>7.2 Calculation and Recovery of the Self-Organization Current Surges' Attractors in the Zirconium Oxyhydrate's Macromolecules with an Optimal Delay</li><li>7.3 Role of the Noise in Excitable Oxyhydrate Systems</li><li>7.4 Analysis of Experimental Poincare Cross-Sections in Zirconium, Oxyhydrate Colloid Gels</li><li>7.5 Conclusions</li><li>Abstract 7.1 Album</li><li>Abstract 7.2 ?able 1. Dimensions and Frequencies of the Clusters Formed in the Zirconium Gel Oxyhydrate Systems</li><li>Abstract 7.3 Table 2. some Data on Ageing of the Zirconium Oxyhydrate Gel</li><li>8. Phase Flow of Oxyhydrate Gels and their Place among the Concepts of Colloid Chemistry</li><li>8.1 Attractors in Colloid Chemical Flow Systems</li><li>8.2 Experimental Manifestation of Alterations in Noise Viscous Parameters of Gel Oxyhydrate Systems when they Flow</li><li>8.3 Formation of Nonequilibrium Oxyhydrate Structures</li><li>8.4 Conclusions</li><li>Abstract 8.1</li><li>9. Optical and other Properties, and Gel Oxyhydrate "noise"</li><li>9.1 Light Absorption Equation on Conformer "Noise" Clusters</li><li>9.2 The Way the Pulsation Noise or Self-Organizational Current in a Magnetic Field Affects Optical Parameters of Zirconium Oxyhydrate</li><li>9.3 Optical Density Kinetic Curves for Yttrium Oxyhydrate Gels</li><li>9.4 Conclusions</li><li>10. "Lag Effect." The Way an External Magnetic Activation Affects Oxyhydrate Gels</li><li>10.1 The Way an External Magnetic Field Affects Toroid Stochastic Noise in a Gel Oxyhydrate System</li><li>10.2 Stable Magnetic Field and Oxyhydrate Gels' Freshly Deposed Residues</li><li>10.3 Conclusions</li><li>References</li></ul>
