Mechanical Properties And Molecular Structure Of Silicon Carbide Hybrid Glasses

Mechanical Properties and Molecular Structure of Silicon Carbide Hybrid Glasses

Author : Yusuke Matsuda

Publisher :

Page : pages

File Size : 48,16 MB

Release : 2012

Category :

ISBN :

Get eBook

Book Description

Silicon carbide hybrid glasses are a class of hybrid organic-inorganic glasses which contain inorganic network bonds and organic monovalent bonds. They exhibit not only excellent thermal and chemical stability, but also unique multi-functionality that is tunable by controlling chemical composition, the number of monovalent bonds, and additional porosity. Perhaps the most significant advantage of silicon carbide hybrid glasses is that they are processed without moisture-sensitive bonds, and therefore they are in theory insensitive to "moisture-assisted cracking, " which significantly deteriorates the mechanical integrity of moisture-sensitive materials. These attractive properties make silicon carbide hybrid glasses promising candidates for emerging nanoscience and energy applications that require protection from moisture and harsh environments. However, the successful integration and application of silicon carbide hybrid glasses are limited by their fragile nature due to the reduced network connectivity and lack of plasticity of the glasses. The central theme of this dissertation is to investigate the fundamental connection between the molecular structure and resulting mechanical properties of silicon carbide hybrid glasses to obtain design guides to improve their mechanical properties, which enables the integration and application of the glasses. The crucial role of glass network connectivity and plasticity in the mechanical properties of the silicon carbide hybrid glasses was first demonstrated. It was shown that the cohesive fracture energy of the silicon carbide hybrid glasses can be dramatically improved by conferring plasticity to the glasses through the incorporation of carbon chains into the molecular structure without sacrificing their excellent thermal and chemical stability. The silicon carbide hybrid glasses with plasticity were also used as toughening layers to dramatically improve adhesion in nanoscale thin-film structures. It was then demonstrated that silicon carbide hybrid glasses exhibited a low sensitivity to moisture-assisted cracking even though they were processed without moisture-sensitive bonds. This low sensitivity was due to the formation of Si--O--Si bonds at Si--Hx bonds in the glasses after the deposition process. A new atomistic kinetic fracture model that incorporates the role of moisture-insensitive bonds was developed to quantitatively predict the low sensitivity and crack growth velocity of the glasses. The developed atomistic kinetic fracture model was further employed to explore how the sensitivity of the glasses to moisture-assisted cracking changed with varying Si--O--Si bonds. Finally, the applicability of a new silicon carbide hybrid glass to an industrial application was explored. This new glass exhibited mechanical properties superior to traditional silica-based hybrid glasses and insensitivity to moisture-assisted cracking.



Molecular Origins of Mechanical Properties in Hybrid Glasses

Author : Mark Stephen Oliver

Publisher : Stanford University

Page : 170 pages

File Size : 27,45 MB

Release : 2010

Category :

ISBN :

Get eBook

Book Description

Hybrid organic-inorganic glasses are materials wherein organic and inorganic chemical components are intermixed and covalently bound at the molecular scale. This class of materials has great potential to enable and enhance a range of new technologies given their unique properties. To date, hybrid glasses have been used in a diverse range of applications including protective coatings, adhesion promoting films, ultra-low-k dielectrics, and optical waveguides. The successful integration of hybrid glasses requires that they possess sufficient mechanical properties to withstand often harsh processing and operating conditions. This dissertation presents results from several investigations of how molecular structure controls elastic and fracture properties of hybrid glasses. Two major sol-gel derived hybrid glass systems are discussed. The first is oxycarbosilane (OCS) glasses processed from small organosilane precursors. The second system is ZrOx/epoxysilane hybrids. For the OCS glasses, the primary focus of this work was to develop the capability to generate accurate molecular models of these materials and to simulate their mechanical properties using molecular dynamics as well as a novel fracture model that uses the mathematics of graph theory to predict the 3-D cohesive fracture path at the atomic scale. Using these computational tools, the impact of network connectivity on elastic stiffness and cohesive fracture energy has been elucidated. Also, the exceptionally high stiffness of OCS materials processed from 1,3,5-benzene precursors predicted by computational modeling is discussed. For the ZrOx/epoxysilane materials, linear elastic fracture mechanics experiments were done to characterize the fracture resistance of these glasses under monotonic, static, and cyclic loading conditions. The effects of glass composition, substrate composition, and silane crosslinking on the critical fracture energy were investigated. Additionally, plasticity-driven cyclic mechanical fatigue was observed, providing the first evidence of the importance of fatigue phenomena to hybrid glasses.



Molecular Origins of Mechanical Properties in Hybrid Glasses

Author : Mark Stephen Oliver

Publisher :

Page : pages

File Size : 12,75 MB

Release : 2010

Category :

ISBN :

Get eBook

Book Description

Hybrid organic-inorganic glasses are materials wherein organic and inorganic chemical components are intermixed and covalently bound at the molecular scale. This class of materials has great potential to enable and enhance a range of new technologies given their unique properties. To date, hybrid glasses have been used in a diverse range of applications including protective coatings, adhesion promoting films, ultra-low-k dielectrics, and optical waveguides. The successful integration of hybrid glasses requires that they possess sufficient mechanical properties to withstand often harsh processing and operating conditions. This dissertation presents results from several investigations of how molecular structure controls elastic and fracture properties of hybrid glasses. Two major sol-gel derived hybrid glass systems are discussed. The first is oxycarbosilane (OCS) glasses processed from small organosilane precursors. The second system is ZrOx/epoxysilane hybrids. For the OCS glasses, the primary focus of this work was to develop the capability to generate accurate molecular models of these materials and to simulate their mechanical properties using molecular dynamics as well as a novel fracture model that uses the mathematics of graph theory to predict the 3-D cohesive fracture path at the atomic scale. Using these computational tools, the impact of network connectivity on elastic stiffness and cohesive fracture energy has been elucidated. Also, the exceptionally high stiffness of OCS materials processed from 1,3,5-benzene precursors predicted by computational modeling is discussed. For the ZrOx/epoxysilane materials, linear elastic fracture mechanics experiments were done to characterize the fracture resistance of these glasses under monotonic, static, and cyclic loading conditions. The effects of glass composition, substrate composition, and silane crosslinking on the critical fracture energy were investigated. Additionally, plasticity-driven cyclic mechanical fatigue was observed, providing the first evidence of the importance of fatigue phenomena to hybrid glasses.







Proceedings of Fourth International Conference on Inventive Material Science Applications

Author : V. Bindhu

Publisher : Springer Nature

Page : 802 pages

File Size : 26,46 MB

Release : 2021-10-19

Category : Technology & Engineering

ISBN : 9811643210

Get eBook

Book Description

The volume is a collection of best selected research papers presented at the 4th International Conference on Inventive Material Science Applications (ICIMA 2021) organized by PPG Institute of Technology, Coimbatore, India during 14 – 15 May 2021. The book includes original research by material science researchers towards developing a compact and efficient functional elements and structures for micro, nano and optoelectronic applications. The book covers important topics like nanomaterials and devices, optoelectronics, sustainable electronic materials, nanocomposites and nanostructures, hybrid electronic materials, medical electronics, computational material science, wearable electronic devices and models, and optical/nano-sensors.



Metallic Glasses

Author : Hu Huang

Publisher : BoD – Books on Demand

Page : 146 pages

File Size : 12,36 MB

Release : 2018-09-19

Category : Technology & Engineering

ISBN : 1789237203

Get eBook

Book Description

Metallic glasses are very promising engineering and functional materials due to their unique mechanical, chemical, and physical properties, attracting increasing attention from both scientific and industrial communities. However, their practical applications are greatly hindered due to three main problems: dimensional limit, poor tension plasticity, and difficulty in machining and shaping. Therefore, further investigation of these issues is urgently required. This book provides readers with recent achievements and developments in the properties and processing of metallic glasses, including mainly thermoplastic forming of metallic glasses (Chapter 2), atomic-level simulation of mechanical deformation of metallic glasses (Chapter 3), metallic glass matrix composites (Chapter 4), and tribo-electrochemical applications of metallic glasses (Chapters 5 and 6).



Properties and Applications of Silicon Carbide

Author : Rosario Gerhardt

Publisher : BoD – Books on Demand

Page : 550 pages

File Size : 49,50 MB

Release : 2011-04-04

Category : Science

ISBN : 9533072016

Get eBook

Book Description

In this book, we explore an eclectic mix of articles that highlight some new potential applications of SiC and different ways to achieve specific properties. Some articles describe well-established processing methods, while others highlight phase equilibria or machining methods. A resurgence of interest in the structural arena is evident, while new ways to utilize the interesting electromagnetic properties of SiC continue to increase.



Composite Structures for Civil and Architectural Engineering

Author : D-H Kim

Publisher : CRC Press

Page : 522 pages

File Size : 37,15 MB

Release : 1994-12-01

Category : Architecture

ISBN : 9780419191704

Get eBook

Book Description

A thorough and understandable guide to the properties and design of structural composites. It derives from the author's many years of experience of research, industrial development and teaching.



Hybrid Fiber Composites

Author : Anish Khan

Publisher : John Wiley & Sons

Page : 438 pages

File Size : 12,77 MB

Release : 2020-06-25

Category : Technology & Engineering

ISBN : 3527824561

Get eBook

Book Description

Fiber-reinforced composites are exceptionally versatile materials whose properties can be tuned to exhibit a variety of favorable properties such as high tensile strength and resistance against wear or chemical and thermal influences. Consequently, these materials are widely used in various industrial fields such as the aircraft, marine, and automobile industry. After an overview of the general structures and properties of hybrid fiber composites, the book focuses on the manufacturing and processing of these materials and their mechanical performance, including the elucidation of failure mechanisms. A comprehensive chapter on the modeling of hybrid fiber composites from micromechanical properties to macro-scale material behavior is followed by a review of applications of these materials in structural engineering, packaging, and the automotive and aerospace industries.