Computational materials science of polymers [[electronic resource] /] / Andrey Aleksandrovich Askadskii |
Autore | Askadskiĭ A. A (Andreĭ Aleksandrovich) |
Pubbl/distr/stampa | Cambridge [England], : Cambridge International Science Pub., 2003 |
Descrizione fisica | 1 online resource (711 p.) |
Disciplina | 668.9 |
Soggetto topico |
Polymers - Mathematical models
Plastics |
Soggetto genere / forma | Electronic books. |
ISBN |
1-280-22604-8
9786610226047 1-904602-32-0 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
PREFACE; INTRODUCTION; Chapter I. Brief information on types of polymers and their chemical structure; Chapter II. Packing of macromolecules and polymer density; II.1. Increments method and basic physical assumptions; II.2. Relationship between free volume of polymers, coefficient of molecular packing and porous structure; Chapter III. Temperature coefficient of volumetric expansion; Chapter IV. Glass transition temperature of polymers; IV.1. Thermomechanical and other methods of evaluation of the glass transition temperature of polymers; IV.2. Mechanism of glass transition
IV.3. Calculation of the glass transition temperature of linear polymersIV.4. Influence of plasticization on the glass transition temperature of polymers; IV.5. Calculation of the glass transition temperature of polymer networks; Chapter V. Temperature of transition into the viscous flow state for amorphous polymers; V.1 Estimation of temperature of transition into the viscous flow state of polymers; V.2 Dependence of Newtonian viscosity on molecular mass of polymer in a wide range of its change; Chapter VI. Melting point of polymers Chapter VII. Temperature of onset of intense thermal degradation of polymersChapter VIII. Optical and opto-mechanical properties of polymers; VIII.1 Refractive index; VIII.2 Stress-optical coefficient; Chapter IX. Dielectric constant of polymers and organic solvents; Chapter X. Equilibrium rubbery modulus for polymer networks; X.1 Calculations of the equilibrium modulus; Chapter XI. Description of relaxation processes in polymers; XI.1 Stress relaxation; XI.2 Sorption and swelling processes; Chapter XII. Solubility of polymers XII.1 Specific cohesive energy of organic liquids and polymers Hildebrand solubility parameterXII.2 Solubility criterion; XII.3 Influence of molecular mass and degree of macromolecule orientation on solubility; Chapter XIII. Surface properties of organic liquids and polymers; XIII.1. Surface tension of organic liquids; XIII.2. Surface tension of polymers; Chapter XIV. Miscibility of polymers; Chapter XVI. Thermophysical properties of polymers; XVI.1 Heat capacity; XVI.2 Thermal diffusivity and heat conductivity Chapter XVII. Molecular design and computer synthesis of polymers with predetermined propertiesAppendix 1. Examples of solution of direct problems of polymer synthesis; Appendix 2. Examples of solving the reverse problem of polymer synthesis; Appendix 3. The example of solving the complex problem ... analysis of the chemical structure of phenol formaldehyde resin; Appendix 4. Application of the approach to multicomponent copolymers; Appendix 5. Influence of strong intermolecular interaction occurring between two dissimilar polymers on their miscibility Appendix 6. On formation of super-molecular structures in amorphous polymers |
Record Nr. | UNINA-9910449850803321 |
Askadskiĭ A. A (Andreĭ Aleksandrovich) | ||
Cambridge [England], : Cambridge International Science Pub., 2003 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Computational materials science of polymers [[electronic resource] /] / Andrey Aleksandrovich Askadskii |
Autore | Askadskiĭ A. A (Andreĭ Aleksandrovich) |
Pubbl/distr/stampa | Cambridge [England], : Cambridge International Science Pub., 2003 |
Descrizione fisica | 1 online resource (711 p.) |
Disciplina | 668.9 |
Soggetto topico |
Polymers - Mathematical models
Plastics |
ISBN |
1-280-22604-8
9786610226047 1-904602-32-0 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
PREFACE; INTRODUCTION; Chapter I. Brief information on types of polymers and their chemical structure; Chapter II. Packing of macromolecules and polymer density; II.1. Increments method and basic physical assumptions; II.2. Relationship between free volume of polymers, coefficient of molecular packing and porous structure; Chapter III. Temperature coefficient of volumetric expansion; Chapter IV. Glass transition temperature of polymers; IV.1. Thermomechanical and other methods of evaluation of the glass transition temperature of polymers; IV.2. Mechanism of glass transition
IV.3. Calculation of the glass transition temperature of linear polymersIV.4. Influence of plasticization on the glass transition temperature of polymers; IV.5. Calculation of the glass transition temperature of polymer networks; Chapter V. Temperature of transition into the viscous flow state for amorphous polymers; V.1 Estimation of temperature of transition into the viscous flow state of polymers; V.2 Dependence of Newtonian viscosity on molecular mass of polymer in a wide range of its change; Chapter VI. Melting point of polymers Chapter VII. Temperature of onset of intense thermal degradation of polymersChapter VIII. Optical and opto-mechanical properties of polymers; VIII.1 Refractive index; VIII.2 Stress-optical coefficient; Chapter IX. Dielectric constant of polymers and organic solvents; Chapter X. Equilibrium rubbery modulus for polymer networks; X.1 Calculations of the equilibrium modulus; Chapter XI. Description of relaxation processes in polymers; XI.1 Stress relaxation; XI.2 Sorption and swelling processes; Chapter XII. Solubility of polymers XII.1 Specific cohesive energy of organic liquids and polymers Hildebrand solubility parameterXII.2 Solubility criterion; XII.3 Influence of molecular mass and degree of macromolecule orientation on solubility; Chapter XIII. Surface properties of organic liquids and polymers; XIII.1. Surface tension of organic liquids; XIII.2. Surface tension of polymers; Chapter XIV. Miscibility of polymers; Chapter XVI. Thermophysical properties of polymers; XVI.1 Heat capacity; XVI.2 Thermal diffusivity and heat conductivity Chapter XVII. Molecular design and computer synthesis of polymers with predetermined propertiesAppendix 1. Examples of solution of direct problems of polymer synthesis; Appendix 2. Examples of solving the reverse problem of polymer synthesis; Appendix 3. The example of solving the complex problem ... analysis of the chemical structure of phenol formaldehyde resin; Appendix 4. Application of the approach to multicomponent copolymers; Appendix 5. Influence of strong intermolecular interaction occurring between two dissimilar polymers on their miscibility Appendix 6. On formation of super-molecular structures in amorphous polymers |
Record Nr. | UNINA-9910777064003321 |
Askadskiĭ A. A (Andreĭ Aleksandrovich) | ||
Cambridge [England], : Cambridge International Science Pub., 2003 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Computational materials science of polymers [[electronic resource] /] / Andrey Aleksandrovich Askadskii |
Autore | Askadskiĭ A. A (Andreĭ Aleksandrovich) |
Pubbl/distr/stampa | Cambridge [England], : Cambridge International Science Pub., 2003 |
Descrizione fisica | 1 online resource (711 p.) |
Disciplina | 668.9 |
Soggetto topico |
Polymers - Mathematical models
Plastics |
ISBN |
1-280-22604-8
9786610226047 1-904602-32-0 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
PREFACE; INTRODUCTION; Chapter I. Brief information on types of polymers and their chemical structure; Chapter II. Packing of macromolecules and polymer density; II.1. Increments method and basic physical assumptions; II.2. Relationship between free volume of polymers, coefficient of molecular packing and porous structure; Chapter III. Temperature coefficient of volumetric expansion; Chapter IV. Glass transition temperature of polymers; IV.1. Thermomechanical and other methods of evaluation of the glass transition temperature of polymers; IV.2. Mechanism of glass transition
IV.3. Calculation of the glass transition temperature of linear polymersIV.4. Influence of plasticization on the glass transition temperature of polymers; IV.5. Calculation of the glass transition temperature of polymer networks; Chapter V. Temperature of transition into the viscous flow state for amorphous polymers; V.1 Estimation of temperature of transition into the viscous flow state of polymers; V.2 Dependence of Newtonian viscosity on molecular mass of polymer in a wide range of its change; Chapter VI. Melting point of polymers Chapter VII. Temperature of onset of intense thermal degradation of polymersChapter VIII. Optical and opto-mechanical properties of polymers; VIII.1 Refractive index; VIII.2 Stress-optical coefficient; Chapter IX. Dielectric constant of polymers and organic solvents; Chapter X. Equilibrium rubbery modulus for polymer networks; X.1 Calculations of the equilibrium modulus; Chapter XI. Description of relaxation processes in polymers; XI.1 Stress relaxation; XI.2 Sorption and swelling processes; Chapter XII. Solubility of polymers XII.1 Specific cohesive energy of organic liquids and polymers Hildebrand solubility parameterXII.2 Solubility criterion; XII.3 Influence of molecular mass and degree of macromolecule orientation on solubility; Chapter XIII. Surface properties of organic liquids and polymers; XIII.1. Surface tension of organic liquids; XIII.2. Surface tension of polymers; Chapter XIV. Miscibility of polymers; Chapter XVI. Thermophysical properties of polymers; XVI.1 Heat capacity; XVI.2 Thermal diffusivity and heat conductivity Chapter XVII. Molecular design and computer synthesis of polymers with predetermined propertiesAppendix 1. Examples of solution of direct problems of polymer synthesis; Appendix 2. Examples of solving the reverse problem of polymer synthesis; Appendix 3. The example of solving the complex problem ... analysis of the chemical structure of phenol formaldehyde resin; Appendix 4. Application of the approach to multicomponent copolymers; Appendix 5. Influence of strong intermolecular interaction occurring between two dissimilar polymers on their miscibility Appendix 6. On formation of super-molecular structures in amorphous polymers |
Record Nr. | UNINA-9910822675203321 |
Askadskiĭ A. A (Andreĭ Aleksandrovich) | ||
Cambridge [England], : Cambridge International Science Pub., 2003 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
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