Book contents
- Frontmatter
- Contents
- Preface
- 1 Introduction
- 2 Polymer physics and rheology
- 3 General quasi-one-dimensional equations of dynamics of free liquid jets, capillary and bending instability
- 4 Melt- and solution blowing
- 5 Electrospinning of micro- and nanofibers
- 6 Additional methods and materials used to form micro- and nanofibers
- 7 Tensile properties of micro- and nanofibers
- 8 Post-processing
- 9 Applications of micro- and nanofibers
- 10 Military applications of micro- and nanofibers
- 11 Applications of micro- and nanofibers, and micro- and nanoparticles: healthcare, nutrition, drug delivery and personal care
- Subject Index
Preface
Published online by Cambridge University Press: 05 June 2014
- Frontmatter
- Contents
- Preface
- 1 Introduction
- 2 Polymer physics and rheology
- 3 General quasi-one-dimensional equations of dynamics of free liquid jets, capillary and bending instability
- 4 Melt- and solution blowing
- 5 Electrospinning of micro- and nanofibers
- 6 Additional methods and materials used to form micro- and nanofibers
- 7 Tensile properties of micro- and nanofibers
- 8 Post-processing
- 9 Applications of micro- and nanofibers
- 10 Military applications of micro- and nanofibers
- 11 Applications of micro- and nanofibers, and micro- and nanoparticles: healthcare, nutrition, drug delivery and personal care
- Subject Index
Summary
Preface
Fiber-forming processes and the resulting fibers have become a key element in many modern technologies. Today, practically everyone is directly or indirectly using these fibers. Manmade macroscopic fibers are widely used in our garments and many other items of everyday life. On the other hand, much smaller microscopic and, especially, nanofibers are only beginning their path to prominence. The chemical, physical and technological aspects of manufacturing of such fibers are still weakly linked and not fully understood. Two main processes associated with formation of micro- and nanofibers are melt- or solution blowing and electrospinning. They require concerted interaction of synthetic chemistry, responsible for polymers used as raw materials, polymer physics, providing a link to their viscoelastic behavior, rheological characterization of flow properties, non-Newtonian fluid dynamics of polymer solutions and melts, aerodynamics, associated with gas blowing, and electrohydrodynamics, in the case of electrospinning. The key element of the fiber-forming processes is a thin jet of polymer solution or melt, which rapidly changes its three-dimensional configuration under the action of the aerodynamic or electric forces applied to its surface and the internal viscous and elastic stresses. There is a definite and imperative need to interpret and rationalize these phenomena, which requires acquisition of extensive experimental data and establishment of an appropriate theoretical framework as an essential element in the further technological design and optimization. In addition to the above-mentioned broad spectrum of disciplines, this involves different aspects associated with materials science, such as the methods developed in polymer crystallography, and elasticity and plasticity theory. Although many aspects of fiber-forming processes can today be considered as uncovered and well described, either experimentally or theoretically/numerically, numerous important details are still to be explored. The importance of this subject is attested by an exponential increase in scientific publications devoted to microscopic and nanofibers and a broad involvement of the industries associated with fiber media, nonwovens, nano-textured materials, novel biomedical and healthcare products and optical fibers, as well as defense applications.
- Type
- Chapter
- Information
- Fundamentals and Applications of Micro- and Nanofibers , pp. ix - xiiPublisher: Cambridge University PressPrint publication year: 2014