Vladimir A. Bershtein,
Pavel N. Yakushev
Springer Nature Switzerland
e druk, 2023
9783031329425
High-Temperature Polymer Nanocomposites Based on Heterocyclic Networks from Nitrile Monomers
Specificaties
Gebonden, blz.
|
Engels
Springer Nature Switzerland |
2023
ISBN13: 9783031329425
Rubricering
Onderdeel van serie
Springer Series in Materials Science
Levertijd ongeveer 9 werkdagen
Gratis verzonden
Samenvatting
This book presents an overview of polymer nanocomposites for use in various high-temperature applications. Specifically, it focuses on the structure and physical properties of nanocomposites based on heterocyclic matrices derived from nitrile monomers such as cyanate esters or phthalonitriles. Due to increasing interest in new heat-resistant, lightweight materials for use in extreme conditions, such as in aeronautics, microelectronics, and various industrial machinery, the high thermal stability of heterocyclic polymer networks, in particular, has attracted much attention from materials researchers and engineers. Featuring a comprehensive review of the most recent advances in research on the structure and physical properties of these promising high-temperature polymer nanocomposites, this book will be of particular interest to materials scientists and engineers working throughout the fields of aeronautical and microelectronic engineering. In general, this book is intended for use by researchers of composite materials and specialists engaged in material selection for work in extreme conditions; for students specializing in materials science; for polymer physicists, and for university libraries.
Specificaties
ISBN13:9783031329425
Taal:Engels
Bindwijze:gebonden
Uitgever:Springer Nature Switzerland
Inhoudsopgave
Preface<p>Abbreviations</p>
<p>Part I. Recent Advances in Studying Cyanate Ester Resin-based </p>
<p> Nanocomposites</p>
Chapter 1. CER/POSS nanocomposites <p></p>
<p> 1.1 Structure of the nanocomposites derived from dicyanate ester of bisphenol E </p>
<p> (DCBE) monomer and PT-30 oligomer</p>
<p> 1.2 Properties of DCBE- and PT-30- based CER/POSS nanocomposites</p>
<p> 1.3 Influence of varying chemical structure of CER matriх on the properties </p>
<p> of POSS containing nanocomposites</p>
<p> Chapter 2. CER/Montmorillonite (MMT) nanocomposites</p>
<p> 2.1 Structure and molecular dynamics of nanocomposites </p>
<p> 2.2 The impact of functionalized MMT nanolayers on the properties of nanocomposites</p>
<p> Chapter 3. Nano- and subnanocomposites with silica units introduced by a sol-gel method</p>
<p> 3.1 Nanostructure</p>
3.2 Molecular dynamics and properties<p></p>
<p> 3.3. The nature of the exceptional impact of ultra-low silica contents on the properties of </p>
<p> CER-based subnano- and nanocomposites</p>
<p> Chapter 4. Other nanocomposites. </p>
4.1 Nanocomposites with silica particles<p></p>
<p> 4.5 Nanocomposites with carbon nanofillers </p>
<p> References</p>
<p>Part II. Recent Advances in Studying Phthalonitrile Nanocomposites </p>
<p> Chapter 5. Phthalonitrile composites with POSS nanoparticles</p>
<p> 5.1. Synthesis and spectroscopic control of molecular structure and mobility</p>
<p> 5.2 Nanostructure</p>
<p> 5.3 Glass transition and dynamic mechanical behavior</p>
<p> 5.4 Other properties</p>
<p> Chapter 6. Phthalonitrile /Montmorillonite nanocomposites: </p>
<p> 6.1 Structure</p>
<p> 6.2 Моlecular dynamics and properties</p>
<p> Chapter 7. Phthalonitrile /metal oxide nanocomposites </p>
<p> 7.1 Phthalonitrile /Titania and ZnO nanocomposites </p>
<p> 7.2 Phthalonitrile /Alumina nanocomposites</p>
Chapter 8. Other
<p>Part I. Recent Advances in Studying Cyanate Ester Resin-based </p>
<p> Nanocomposites</p>
Chapter 1. CER/POSS nanocomposites <p></p>
<p> 1.1 Structure of the nanocomposites derived from dicyanate ester of bisphenol E </p>
<p> (DCBE) monomer and PT-30 oligomer</p>
<p> 1.2 Properties of DCBE- and PT-30- based CER/POSS nanocomposites</p>
<p> 1.3 Influence of varying chemical structure of CER matriх on the properties </p>
<p> of POSS containing nanocomposites</p>
<p> Chapter 2. CER/Montmorillonite (MMT) nanocomposites</p>
<p> 2.1 Structure and molecular dynamics of nanocomposites </p>
<p> 2.2 The impact of functionalized MMT nanolayers on the properties of nanocomposites</p>
<p> Chapter 3. Nano- and subnanocomposites with silica units introduced by a sol-gel method</p>
<p> 3.1 Nanostructure</p>
3.2 Molecular dynamics and properties<p></p>
<p> 3.3. The nature of the exceptional impact of ultra-low silica contents on the properties of </p>
<p> CER-based subnano- and nanocomposites</p>
<p> Chapter 4. Other nanocomposites. </p>
4.1 Nanocomposites with silica particles<p></p>
<p> 4.5 Nanocomposites with carbon nanofillers </p>
<p> References</p>
<p>Part II. Recent Advances in Studying Phthalonitrile Nanocomposites </p>
<p> Chapter 5. Phthalonitrile composites with POSS nanoparticles</p>
<p> 5.1. Synthesis and spectroscopic control of molecular structure and mobility</p>
<p> 5.2 Nanostructure</p>
<p> 5.3 Glass transition and dynamic mechanical behavior</p>
<p> 5.4 Other properties</p>
<p> Chapter 6. Phthalonitrile /Montmorillonite nanocomposites: </p>
<p> 6.1 Structure</p>
<p> 6.2 Моlecular dynamics and properties</p>
<p> Chapter 7. Phthalonitrile /metal oxide nanocomposites </p>
<p> 7.1 Phthalonitrile /Titania and ZnO nanocomposites </p>
<p> 7.2 Phthalonitrile /Alumina nanocomposites</p>
Chapter 8. Other