Nonlinearity of colloid systems : oxyhydrate systems

The present monograph is the first systematic study of the non-linear characteristic of gel oxy-hydrate systems involving d- and f- elements. These are the oxyhydrates of rare-earth elements and oxides - hydroxides of d- elements (zirconium, niobium, titanium, etc.) The non-linearity of these gel systems introduces fundamental peculiarities into their structure and, consequently, their properties.

Preface Table of Contents 1. Introduction 2. Genesis of Gel Oxyhydrate Systems of D- and F-Elements in the Course of their Formation Second Section's Title 2.1 Modelling of Autowave Processes in Forming Oxyhydrate Gels of Heavy Metals 2.2 Modelling of Active, Easily Excitable Gel Media 2.3 Research of Gels in Active, Easily Excitable Medium by Molecular Dynamics and Monte-Carlo Methods 2.4 Genesis of Oxyhydrate and Phosphate Gels (Experimentally Observed) 2.5 Conclusions 3. Periodic Phenomena of the Organization of Gel Oxyhydrate Systems 3.1 Analysis of Structurization Processes in Gel Systems 3.2 Quantization of Attractor (Pacemaker) Radii 3.3 Conclusions 4. Dilatancy Effect as A Specific Property of Periodicity of Gel Oxyhydrates 4.1 An Effect of Periodic Dilatancy in Oxyhydrate Gel Systems 4.2 Volumetric Dilatancy and Pacemaker Sizes 4.3 Conclusions 5. Liesegang Operator as a Reflection of Nonlinearpropertiesof Oxyhydrate Gel Systems. 5.1 Liesegang Rings as a Universal Gross-Property Ofgelpolymer Systems. 5.2 Self-Coordination (Self-Assembly) of Gel Fragments 5.3 Physico-Chemical Interpretation of Liesegang Operator 5.4 Conclusions 6. Mesophase-Like Behaviour of Gel Systems 6.1 Formation of the Structured Elements of Zirconium Oxyhydrate Gels under Non-Equilibrium Conditions 6.2 Study of Polymeric Fragments of Niobium Oxyhydrate 6.3 Properties of the Liquid-Crystalline State of Gel Oxyhydrates that Develop with Time 6.4 Liquid-Crystal Features of Zirconium Oxyhydrate Gels. Model Studies 7. The Chromatic Effect of some Oxyhydrate Gels 7.1 Colouring of Oxyhydrate Gels of Heavy Metals 7.2 Study of Absorption Spectra of [ZrO(OH)2]n Polymer by Quantum Chemical Methods 7.4 Conclusions 8. Experimental Studies of Optical Properties of Gels. Observed Chromatic Effect . 8.1 Optical Properties of Zirconium Oxyhydrate 8.2 Structural Features and Optical Properties of Polymeric Gels of Yttrium Oxyhydrate 8.3 Structural Evolution of Oxyhydrates of Heavy Metals and Electromagnetic Radiation 8.4 Synthesis and Properties of the Coloured Gels of Zirconium Oxyhydrate 8.5 Coloured Gels of Niobium Oxyhydrate 8.6 Effect of the Nature of Metal and Shear Strains on the Optical Spectra and Colouring of Oxyhydrate Gels 8.7 Synthesis of the Coloured Gels of Lanthanum and Yttrium Oxyhydrates 8.8 Conclusions 9. The Phisico-Chemical Nature of Polarisation of Living Gels of Heavy Metals Oxyhydrates 9.1 Introduction of Liesegang Operator, the Polarisation Operator 9.2 A Mechanism of Gel Polarization Conductivity. Rotational Motion of Polarization 9.3 Conclusions 10. The Influence of Electric, Magnetic and Electromagnetic Fields on the Structurization Processes of Yttrium Oxyhydrate 10.1 The Effect of the Static Magnetic and Electric Field on Gels 10.2 The Effect of Electromagnetic Radiation on Sorption Properties of Yttrium Oxyhydrate 10.3 The Effect of Electromagnetic Radiation on the Processes of Yttrium Oxyhydrate Formation 10.4 Conclusions 11. Nonlinear Sorption Properties of Oxyhydrate. 11.1 Experimental Studies of the Sorption System State "lanthanum Oxyhydrate - Own-Salt Solution" under Isothermal Conditions 11.2 Kinetics of the Process of Sorption-Peptization Self-Organization of Ytterbium and Gadolinium Oxyhydrate Gels 11.3 Kinetics of Sorption Processes in "zirconium Oxyhydrate - Yttrium Nitrate" Systems 11.4 Conclusion 12. Quantum Chemical Study Of The Structural Models Of Zirconium Oxyhydrate 12.1 Polymerisation of Zirconium Oxyhydrate Gels 12.2 Hydration of Zirconium Oxyhydrate Gels 12.3 Creation of Macromolecular Formations of Zirconium Oxyhydrate 12.4 Conclusion 13. In Place of A Conclusion References