Functional Materials and Materials Reliability
Published on 10. July 2023
Book
Paperback/Softback
220 pages
978-3-0364-0323-6 (ISBN)
Description
This special issue presents the research results and engineering developments in the area of silicon carbide semiconductor materials for power electronics and the latest composite and polymer materials for machinery and textile production. The special edition will be useful to engineers whose activity is related to research and developments in the area of power electronics and modern composite and polymer materials.
This special issue presents the research results and engineering developments in the area of silicon carbide semiconductor materials for power electronics and the latest composite and polymer materials for machinery and textile production. The special edition will be useful to engineers whose activity is related to research and developments in the area of power electronics and modern composite and polymer materials.
More details
Series
Language
English
Place of publication
Zurich
Switzerland
Target group
Professional and scholarly
Illustrations
Illustrations, unspecified
Dimensions
Height: 240 mm
Width: 170 mm
Thickness: 11 mm
Weight
510 gr
ISBN-13
978-3-0364-0323-6 (9783036403236)
DOI
10.4028/b-xGEh9H
Copyright in bibliographic data and cover images is held by Nielsen Book Services Limited or by the publishers or by their respective licensors: all rights reserved.
Schweitzer Classification
Other editions
Additional editions
Juraj Marek | Gregor Pobegen | Ulrike Grossner
Functional Materials and Materials Reliability
E-Book
06/2023
Trans Tech Publications Ltd
€203.30
Available for download
Content
<ul><li>Preface</li><li>Chapter 1: Composite Materials and Structures</li><li>Control of the Deformation Mode of Aluminum Foam-Filled Tubes as a Function of Foam Porosity</li><li>Crashworthiness Analysis of Vehicle Crash-Box Filled with Aluminium Foam</li><li>Improving Fiber-Matrix Compatibility by Surface Modification of Coconut Coir Fiber Using White Rot Fungi</li><li>Ramie Fiber Woven Composite: The Effect of Feedrate Variation on the Tensile Strength of the Open Hole in the Drilling</li><li>Mathematical Model of Shear Stress Transfer at Fiber-Matrix Interface of Composite Material</li><li>Study on the Mechanical Properties and Behavior of Corrugated Cardboard under Tensile and Compression Loads</li><li>Chapter 2: Functional Materials</li><li>Modification of Polyester Properties through Functionalization with PVA</li><li>Cellulosic Textile Materials Functionalization with Formic Acid and Improvement of their Properties</li><li>First-Principles Insights into the Acetic Acid Sensing Capability of the C<sub>39</sub>N Armchair Nanotube</li><li>Chapter 3: Reliability of Silicon Carbide Metal Oxide Semiconductor Devices</li><li>Bias-Induced Instability of 4H-SiC CMOS</li><li>On the Frequency Dependence of the Gate Switching Instability in Silicon Carbide MOSFETs</li><li>Robustness of SiC MOSFETs under Repetitive High Current Pulses</li><li>Reliability of SiC MOSFET Power Modules under Consecutive H3TRB and Power Cycling Stress</li><li>Chip-Top Packaging Technology for SiC Devices Operational at 250 degreesC with Power-Cycling Durability of over 300,000 Cycles</li><li>Avalanche Robustness Investigation of SiC Avalanche Diodes at High Temperatures</li><li>AC-Stress Degradation in SiC MOSFETs</li><li>Power Cycling on Lateral GaN and ?-Ga<sub>2</sub>O<sub>3</sub> Transistors</li><li>Temperature Dependence of the Channel and Drift Resistance of SiC Power MOSFETs Extracted from I-V and C-V Measurements</li><li>Humidity Robustness of 3.3kV SiC-MOSFETs for Traction Applications - Compared to Standard Silicon IGBTs in Identical Packages</li><li>Reliability and Standardization for SiC Power Devices</li><li>Energy-Dependent Impact of Proton Irradiation on 4H-SiC Schottky Diodes</li><li>Impact of Bias Temperature Instabilities on the Performance of Power Electronics Employing SiC MOSFETs</li><li>Proven Power Cycling Reliability of Ohmic Annealing Free SiC Power Device through the Use of SmartSiC<sup>TM</sup> Substrate</li></ul>