Functional Dielectrics for Electronics Books

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Functional Dielectrics for Electronics


Functional Dielectrics for Electronics
  • Author : Yuriy M. Poplavko
  • Publisher : Woodhead Publishing Limited
  • Release : 2020-01-17
  • ISBN : 9780128188354
  • Language : En, Es, Fr & De
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Functional Dielectrics for Electronics: Fundamentals of Conversion Properties presents an overview of the nature of electrical polarization, dielectric nonlinearity, electrical charge transfer mechanisms, thermal properties, the nature of high permittivity, low-loss thermostability and other functional dielectrics. The book describes the intrinsic mechanisms of electrical polarization and the energy transformations in non-centrosymmetric crystals that are responsible for converting thermal, mechanical, optical and other impacts into electrical signals. In addition, the book reviews the main physical processes that provide electrical, mechanoelectrical, thermoelectrical and other conversion phenomena in polar crystals. Detailed descriptions are given to electrical manifestations of polar-sensitivity in the crystals, the interaction of polarization with conductivity, the anomalies in thermal expansion coefficient and main peculiarities of heat transfer in polar-sensitive crystals. Provides readers with a fundamental understanding of polar dielectric materials and their physical processes Includes different models of polar sensitivity and experimental confirmation of these models Discusses thermal expansion, heat transfer, dielectric nonlinearity and other important aspects for electronics applications

IPC 4592 Requirements for Printed Electronics Functional Dielectric Materials


IPC 4592 Requirements for Printed Electronics Functional Dielectric Materials
  • Author : Ipc
  • Publisher :
  • Release : 2021-04-30
  • ISBN : 1638160163
  • Language : En, Es, Fr & De
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Fluorinated Graphene Dielectric and Functional Layers for Electronic Applications


Fluorinated Graphene Dielectric and Functional Layers for Electronic Applications
  • Author : Irina V. Antonova
  • Publisher :
  • Release : 2017
  • ISBN : OCLC:1154270471
  • Language : En, Es, Fr & De
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Future electronics technology is expected to develop from rigid to flexible devices. This process requires breakthroughs in material properties, especially flexibility, in combination with desirable electrical insulating, semiconducting, or metallic properties. Graphene, being one of the recently developed two-dimensional (2D) materials, presents great promise as an active layer in a wide spectrum of electronics devices and, first of all, in field-effect transistors (FET). The development of optimized dielectrics for the graphene active layer is critical for graphene applications. The carrier transport in graphene films takes place at interfaces with dielectric or semiconductor substrates; therefore, the quality of such interface and the interaction of graphene films with nearby dielectric layers (charge carrier scattering) determine the device performance. Generally, the development of dielectric materials aiming at high performance device operation, proper mechanical properties, and low-temperature fabrication is not progressing well since the graphene thin film is very sensitive to surface conditions of dielectric layers. Solving the problem with dielectric layers in the case of nonorganic printed and flexible electronics is especially acute. As it is demonstrated in the present chapter, dielectric layers fabricated from fluorinated graphene suspension or in its combination with graphene oxide are the most promising for graphene-based flexible, printed, and transparent electronics.

Graphene Materials


Graphene Materials
  • Author : George Kyzas
  • Publisher : BoD – Books on Demand
  • Release : 2017-05-17
  • ISBN : 9789535131410
  • Language : En, Es, Fr & De
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Graphene is, basically, a single atomic layer of graphite, an abundant mineral that is an allotrope of carbon that is made up of very tightly bonded carbon atoms organized into a hexagonal lattice. What makes graphene so special is its sp2 hybridization and very thin atomic thickness (of 0.345 Nm). These properties are what enable graphene to break so many records in terms of strength, electricity, and heat conduction (as well as many others). This book gathers valuable information about many advanced applications of graphene (electrical, optical, environmental, cells, capacitors, etc).

Dielectric Breakdown in Gigascale Electronics


Dielectric Breakdown in Gigascale Electronics
  • Author : Juan Pablo Borja
  • Publisher : Springer
  • Release : 2016-09-16
  • ISBN : 9783319432205
  • Language : En, Es, Fr & De
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This book focuses on the experimental and theoretical aspects of the time-dependent breakdown of advanced dielectric films used in gigascale electronics. Coverage includes the most important failure mechanisms for thin low-k films, new and established experimental techniques, recent advances in the area of dielectric failure, and advanced simulations/models to resolve and predict dielectric breakdown, all of which are of considerable importance for engineers and scientists working on developing and integrating present and future chip architectures. The book is specifically designed to aid scientists in assessing the reliability and robustness of electronic systems employing low-k dielectric materials such as nano-porous films. Similarly, the models presented here will help to improve current methodologies for estimating the failure of gigascale electronics at device operating conditions from accelerated lab test conditions. Numerous graphs, tables, and illustrations are included to facilitate understanding of the topics. Readers will be able to understand dielectric breakdown in thin films along with the main failure modes and characterization techniques. In addition, they will gain expertise on conventional as well as new field acceleration test models for predicting long term dielectric degradation.