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…mehr
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.
Produktdetails
Produktdetails
Elsevier Series on Tribology and Surface Engineering
Deyuan Zhang is Professor and former director of the Department of Mechanical Engineering and Automation, Beihang University. His main research focus is on bionic-bio-manufacturing and ultrasonic processing technology. He is a sponsor member of the International Society of Bionic Engineering, director of Biological Manufacturing Branch, and committee director of Ultrasonic Machining from Non-traditional Machining Branch in the Chinese Mechanical Engineering Society (CMES). He has undertaken more than 10 key projects from the National 863 Program, the National Nature Science Foundation, and the General Armaments Department. He is also principle investigator of more than 20 major engineering projects from industrial enterprises. He has published more than 300 papers, including one in Nature of which he was the corresponding author, and filed more than 40 patents.
Yonggang Jiang is Professor, School of Mechanical Engineering and Automation, Beihang University. His main research focus includes biomimetic perception and microelectromechanical sensor development. He is a member of the International Society of Bionic Engineering Youth Commission, a senior member of Chinese Society of Mechanical Engineering, and a senior member of Chinese Society of Micro-Nano Technology. He has published more than 40 SCI-indexed papers and filed more than 15 patents.
Inhaltsangabe
1. Characterization Methods of the Drag Reduction/Increase on the Biologic Micro/Nano Surface 2. Characterization of Natural Super-Slippery and Strong Attachment Surfaces 3. Electron and Ion Transport Theory at Micro/Nano Interface of Cells 4. Universality Analysis of the Biologic Micro/Nano Surface/Interface Energy Field Effect 5. Drag Increase in Micro/Nano-Bionic Surface Enhancing Force Perception 6. Bioinspired Drag Reduction Surface 7. Wave-Motion Wetting in Bionic Micro/Nano Interface for High-Efficient Machining 8. Bioinspired Functional Surfaces for Medical Devices 9. Biomimetic Modification of Cells for Enhanced Energy Field Effects 10. Engineering Analysis of the Manufacturing Technologies for the Bionic Micro/Nano Surface/Interface
1. Characterization Methods of the Drag Reduction/Increase on the Biologic Micro/Nano Surface 2. Characterization of Natural Super-Slippery and Strong Attachment Surfaces 3. Electron and Ion Transport Theory at Micro/Nano Interface of Cells 4. Universality Analysis of the Biologic Micro/Nano Surface/Interface Energy Field Effect 5. Drag Increase in Micro/Nano-Bionic Surface Enhancing Force Perception 6. Bioinspired Drag Reduction Surface 7. Wave-Motion Wetting in Bionic Micro/Nano Interface for High-Efficient Machining 8. Bioinspired Functional Surfaces for Medical Devices 9. Biomimetic Modification of Cells for Enhanced Energy Field Effects 10. Engineering Analysis of the Manufacturing Technologies for the Bionic Micro/Nano Surface/Interface
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