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EB

EB

ONLINE

Amsterdam : Elsevier, 2021

1 online resource illustrations (black and white, and colour)

ISBN 0128245034

ISBN 9780128245026 (electronic bk.)

ISBN 0128245026 (electronic bk.)

ISBN 9780128245033 (pbk.) (e-book)

Micro- and Nano-Bionic Surfaces: Biomimetics, Interface Energy Field Effects, and Applications synthesizes the latest research in bio-inspired surfaces and devices for tactile and flow field perception. The book provides solutions to common problems related to flow field/tactile perception, intelligent MEMS sensors, smart materials, material removal methods, cell/particle control methods, and micro-nano robot technology. With a heavy emphasis on applications throughout, the book starts by providing insights into biomimetic device design, outlining strategies readers can adopt for various engineering applications. From there, it introduces the controlling methods of smart materials, controlling methods from external energy input, and more. Sections demonstrate how to solve problems of high efficiency, high quality, and low damage material removal for metals, composites, soft tissues, and other materials by applying bionic wave-motion surface characteristics. The latest theoretical and technical developments in field control methods applied to biological interfaces are also discussed, and the book concludes with a chapter on fabrication strategies to synthesize micro/nano functional particles based on bio-templates..

001931762

Intro -- Micro- and Nano-Bionic Surfaces: Biomimetics, Interface Energy Field Effects, and Applications -- Copyright -- Contents -- Chapter 1: Introduction -- 1.1. Historical limitations of traditional mechanical surface/machining interface theories -- 1.2. Theoretical issues in characterizing the energy fields of biological surfaces/feed apparatus -- 1.3. Issues of design and manufacturing in bionic mechanical surface/machining interface -- 1.4. Promotion of micro/nano bionic surface/interface to human development -- 1.5. Main contents and purposes of this book -- References -- Part I: Characterization of energy field effects on the micro/nano biological surface/interfaces -- Chapter 2: Classification of micro/nano biological surface/interface energy field effect from mechanical perspective -- 2.1. Huge gaps between mechanical and biological surface/interface energy field effects -- 2.2. Huge gaps between mechanical and biological surface/interface structures -- 2.3. Characterization methods of biological micro/nano surface/interface energy field effect -- References -- Chapter 3: Characterization of biological micro/nano surfaces drag-increase and drag-reduction structures -- 3.1. Characterization and theoretical issues of drag-increase structures in cavefish lateral line -- 3.1.1. Drag-increase structures in cavefish lateral line -- 3.1.2. Drag-increase effect and theoretical issues in cavefish lateral line -- 3.2. Characterization and theoretical issues of drag-reduction structure of shark skin -- 3.2.1. The feature structure and mucus of shark skin and its drag-reduction performance -- 3.2.2. Theoretical issues of shark skin drag-reduction effect --

3.2.2.1. The drag-reduction mechanism of secondary vortex -- 3.2.2.2. The polymer long chain drag-reduction -- 3.2.2.3. Synergistic drag-reduction mechanism -- References -- Chapter 4: Characterization of biological micro/nano interfacial structures for friction reduction and friction increase -- 4.1. Characterization of interface structures on Nepenthes alata for friction reduction and the related theoretical models -- 4.1.1. Characterization of structures and phenomena on Nepenthes alata for friction reduction -- 4.1.2. Theories for friction reduction effects on Nepenthes alata -- 4.1.3. Theories for wave-mode friction reduction -- 4.2. The strong wet friction of tree frog’s toe pad -- 4.2.1. Structure and friction characteristic of tree frog toe pad -- 4.2.2. The strong boundary friction from the capillarity of nano-thickness liquid film -- References -- Chapter 5: Transport and deposition structure of cell nano interface -- 5.1. Characterization and theoretical issues of membrane oxidation structure of Thiobacillus ferrooxidans -- 5.1.1. Oxidation structure and reaction model of Thiobacillus ferrooxidans membrane

(OCoLC)1289813129