
Micro- and Nano-Bionic Surfaces
Biomimetics, Interface Energy Field Effects, and Applications
Description
Key Features
- Provides an overview on the latest research in bio-inspired surfaces and devices for tactile and flow-field perception
- Introduces techniques for characterizing different bionic surfaces and how to use energy fields analysis to treat different bionic surface and interface problems
- Discusses the latest theoretical and experimental developments in field control and their applications in the biomedical field
- Outlines fabrication methods and assembly and alignment processes of micro-/nano-functional particles based on microorganism templates
Readership
Researchers and graduate students working on biosurfaces, interface and structure characterizations, smart materials, flow field/tactile perceptions, MEMS sensor principles, cell/particle behavior. Engineers working on MEMS sensors, smart materials design and manufacture, machining, soft tissue cutting, surgical operation, cell/particle operation, fluid dynamics, and control
Table of Contents
- Cover image
- Title page
- Table of Contents
- Copyright
- 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
- Abstract
- 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
- Abstract
- 3.1: Characterization and theoretical issues of drag-increase structures in cavefish lateral line
- 3.2: Characterization and theoretical issues of drag-reduction structure of shark skin
- References
- Chapter 4: Characterization of biological micro/nano interfacial structures for friction reduction and friction increase
- Abstract
- 4.1: Characterization of interface structures on Nepenthes alata for friction reduction and the related theoretical models
- 4.2: The strong wet friction of tree frog's toe pad
- References
- Chapter 5: Transport and deposition structure of cell nano interface
- Abstract
- 5.1: Characterization and theoretical issues of membrane oxidation structure of Thiobacillus ferrooxidans
- 5.2: Functional micro/nanoparticles (MNPs) based on intracellular deposition in bio-template interface
- 5.3: Characterization and theoretical issues of the interfacial interactions between nanomaterials and cell membrane
- References
- Chapter 6: Analysis of universality and diversity of biological surface/interface energy field effect
- Abstract
- 6.1: Universal analysis of biological surface/interface energy field effects
- 6.2: Diversity analysis of mechanical energy field effects on biological surface/interface
- References
- Part II: Applications of energy field effects on the micro- and nano-bionic surface/interfaces
- Chapter 7: Classification of micro/nano bionic surface/interface energy field effect from biological perspective
- Abstract
- 7.1: Classification and key points of bionic morphological design approaches based on the transfer of surface/interface energy field effects to machinery
- 7.2: Classification and difficulties of bionic structure creation pathways based on the transfer of surface/interface energy field effects to machinery
- 7.3: Classification and difficulties of bionic system integration approaches based on the transfer of surface/interface energy field effects to machinery
- References
- Chapter 8: Bioinspired interfacial drag-increase structure enhancing force perception
- Abstract
- 8.1: Underwater velocity sensors inspired by the drag-increase structures in cavefish lateral line
- 8.2: Underwater pressure difference sensors inspired by the drag-increase structures in cavefish lateral line
- 8.3: Tactile sensors inspired by the drag-increase structures in tree frog toe/human finger
- References
- Chapter 9: Bionic drag reduction surface from shark skin and bioinspired anti-icing surface from superhydrophobic lotus leaf
- Abstract
- 9.1: Fabrication methods of bionic drag reduction surface
- 9.2: Drag reduction effect of bionic shark skin surface
- 9.3: Bioinspired anti-icing surface from superhydrophobic lotus leaf
- References
- Chapter 10: Surgical instruments with lubrication and friction enhancement through bioinspired surfaces
- Abstract
- 10.1: Bioinspired surfaces on monopolar electrosurgical electrode with lubrication enhancement
- 10.2: Bioinspired electrosurgical electrode with wave-mode dry lubrication enhancement
- 10.3: Bioinspired strong wet attachment surfaces in medical application
- References
- Further reading
- Chapter 11: Bionic interfaces lubrication enhancement wave motion machining technology—A high-speed ultrasonic vibration cutting technology
- Abstract
- 11.1: Bionic interfaces lubrication enhancement wave motion cutting (HUVC) technology
- 11.2: Bionic interfaces dry lubrication enhancement wave motion hole-making technology
- References
- Chapter 12: Functional micro-/nanoparticles based on interfacial biotemplated fabrication
- Abstract
- 12.1: Functional MNPs based on extracellular deposition on biotemplate surface
- 12.2: Magnetic cellular robot based on cell phagocytosis
- References
- Chapter 13: Breakthrough analysis of energy field effects on the micro/nano bionic surface/interfaces
- Abstract
- 13.1: Breakthrough analysis of biological/bionic approaches to improve the work efficiency of generalized mechanical surfaces
- 13.2: Breakthrough analysis of biological/bionic approaches to improve the process efficiency of generalized mechanical manufacturing interfaces
- 13.3: Breakthrough analysis of ecological/imitation ecological approaches to improve the operating efficiency of generalized broad manufacturing interface
- 13.4: Prospects for the development direction of natural deep-compatible broad bionics
- References
- Index
Product details
- No. of pages: 358
- Language: English
- Copyright: © Elsevier 2021
- Published: October 28, 2021
- Imprint: Elsevier
- Paperback ISBN: 9780128245026
- eBook ISBN: 9780128245033
About the Authors
Deyuan Zhang
Affiliations and Expertise
Yonggang Jiang
Affiliations and Expertise
Huawei Chen
Affiliations and Expertise
Xiangyu Zhang
Affiliations and Expertise
Lin Feng
Affiliations and Expertise
Jun Cai
Affiliations and Expertise
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