Progress in materials science and engineering is closely related to material properties. It is because materials' performance is closely related to the microstructure. Therefore at present, many modern microscopic studying techniques are used in materials science. Those methods have evolved over decades, or even centuries, from quite rudimentary tools to highly sophisticated equipment. They are necessary for both the quality control of products and the development of new materials. The technical context of measuring materials' properties ranges from fundamental science to reasonably practical "real-world" field tests that can predict performance and-one hopes-prevent machines components failure. In this book, contributions on the following topics were particularly encouraged: optical and mechanical characterization of coarse-grained and nanostructured materials; correlative analysis of microscopic and mechanical properties of surface engineered materials; properties of a new generation of biomorphic materials; validation of the materials' performance in "real-world" tests.
Progress in materials science and engineering is closely related to material properties. It is because materials' performance is closely related to the microstructure. Therefore at present, many modern microscopic studying techniques are used in materials science. Those methods have evolved over decades, or even centuries, from quite rudimentary tools to highly sophisticated equipment. They are necessary for both the quality control of products and the development of new materials. The technical context of measuring materials' properties ranges from fundamental science to reasonably practical "real-world" field tests that can predict performance and-one hopes-prevent machines components failure. In this book, contributions on the following topics were particularly encouraged: optical and mechanical characterization of coarse-grained and nanostructured materials; correlative analysis of microscopic and mechanical properties of surface engineered materials; properties of a new generation of biomorphic materials; validation of the materials' performance in "real-world" tests.
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978-3-0357-3813-1 (9783035738131)
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<ul><li>Preface</li><li>Chapter 1: Physicochemical Properties of Materials</li><li>Influence of Electrochemically Exfoliated Graphite Addition on the Dielectric Properties of Epoxy/Montmorillonite Nanocomposites</li><li>Study of the Optical Properties of Electrospun PAN/GO Nanocomposites</li><li>Mechanical and Tibological Properties of SLM AlSi10Mg Alloy Subjected to ECAP</li><li>Influence of Post-Processing and the Type of Filling on Strength Properties of Elements Printed by Stereolithography Technology</li><li>Mechanism of Cavitation Wear of a Low-Friction Composite Coating CrN+WC/C Deposed on Ferritic-Pearlitic P265GH and Austenitic X2CrNi18-9 (304L) Steels</li><li>Evaluation of Physicochemical and Electrochemical Properties of Surface Modified Pure Titanium Grade II</li><li>Effect of the Nanostructures Addition on TiO<sub>2</sub> Photoanode and DSSC Properties</li><li>Structure of N-Layer Film Obtained by Developed Blow Molding Process</li><li>Chapter 2: Morphological and Microstructural Investigation of Materials</li><li>Effect of Al10Sr and TiB on the Microstructure and Solidification Behavior of AlMg5Si2Mn Alloy</li><li>Influence of the ECAP Tool Channel Geometry on the Structure and Properties of Al-3%Mg Aluminium Alloy</li><li>Microstructure and Hardness of AlMg3 Alloy Subjected to Ultrasonic Upsetting</li><li>Microstructure and Properties of the Aluminum Alloyed with ZrO Powder Using Fiber Laser</li><li>Laser Cladding Cermet Coatings on Niobium Substrate</li><li>Chemical Composition of Alloys as Primary Material Property Influencing the Accuracy of Measurements Obtained in Energy-Dispersive X-Ray Spectroscopy (EDS), Wavelength-Dispersive X-Ray Spectroscopy (WDX) and X-Ray Fluorescence (XRF)</li></ul>
