Edward Bormashenko – författare

Development of bioinspired materials and metamaterials has changed the philosophy of materials engineering and opened new technological possibilities, as they demonstrate properties that are not found in naturally occurring materials. This book examines advances in these emerging materials classes and investigates how their tailor-engineered properties, such as specific surface energy or refraction index, enable the design of devices and ultimately the ability to solve complex societal problems that are, in principle, impossible with traditional materials.The aim of this book is to survey the scientific foundations of the design and properties of bioinspired materials and metamaterials and the way they enter engineering applications.Introduces the physico-chemical foundations, theoretical groundings, and main equations of biomimetic and metamaterials scienceDescribes how to develop and design these advanced materials and their applicationsFeatures end-of-chapter problems to help readers apply the principlesSurveys achievements including metamaterials cloaking and the negative mass effectEmphasizes ecological aspects of materials scienceThe text is intended for materials engineering students who have completed courses in general physics, chemistry, and calculus, as well as researchers in materials science and engineering.

Development of bioinspired materials and metamaterials has changed the philosophy of materials engineering and opened new technological possibilities, as they demonstrate properties that are not found in naturally occurring materials. This book examines advances in these emerging materials classes and investigates how their tailor-engineered properties, such as specific surface energy or refraction index, enable the design of devices and ultimately the ability to solve complex societal problems that are, in principle, impossible with traditional materials.The aim of this book is to survey the scientific foundations of the design and properties of bioinspired materials and metamaterials and the way they enter engineering applications.Introduces the physico-chemical foundations, theoretical groundings, and main equations of biomimetic and metamaterials scienceDescribes how to develop and design these advanced materials and their applicationsFeatures end-of-chapter problems to help readers apply the principlesSurveys achievements including metamaterials cloaking and the negative mass effectEmphasizes ecological aspects of materials scienceThe text is intended for materials engineering students who have completed courses in general physics, chemistry, and calculus, as well as researchers in materials science and engineering.

This book offers a complete and concise overview of the different strategies used to prepare microstructured surfaces employing information regarding surface instabilities and physical processes. Based upon the concept of the remarkably uniform layer of water vapor that is applied when one simply breathes onto a surface in cold temperatures, the book presents a comprehensive treatise addressing chemical and physical fundamentals, fabrication, and applications of the breath figures approach to surface wetting, coating, and modification (breath figures self-assembly) of various materials. The main topics of the book are divided into six parts: the control of surface properties in polymer blends; block copolymer design with the aim of providing order at different lengths; combination of block copolymer blends with the breath figures (BFs); dynamic templating; the breath figures method; biorecognition; and alternative approaches for surface structuring and functionalization.Discusses various physical processing methods in preparing microstructured surfaces;Describes relevant aspects of micro- and nanostructured surfaces from fabrication to final applications, including additive manufacturing, bacterial adhesion and entrapment, optical and electro-optical applications, and membrane technology; Details the breath figures approach to surface structuring while discussing alternative strategies that tie morphology to functionality of materials.