Electrospun Nanofibers and their ApplicationsRapra Technology Ltd.December 1, 2008 257 Pages - SKU: CACQ2406701 |
- 1. Introduction
- 1.1 What is nanotechnology
- 1.2 What is electrospinning
- 1.3 What affects electrospinning
- 1.4 Applications
- 1.5 Global Interest in the field of Electrospinning
- 2. Mathematical Models for Electrospinning Process
- 2.1 One-dimensional Model
- 2.2 Spivak-Dzenis model
- 2.3 Wan-Guo-Pan Model
- 2.4 Modified One-Dimensional Model
- 2.5 Modified Conservation of Charge
- 2.6 Renekers model
- 2.7 E-Infinity theory
- 3. Allometric Scaling in Electrospinning
- 3.1 Allometric Scaling in Nature
- 3.2 Allometrical Scaling Laws in Electrospinning
- 3.2.1 Relationship between radius r of jet and the axial distance z
- 3.2.2 Allometric scaling relationship between current and voltage
- 3.2.3 Allometric scaling relation between solution flow rate and current
- 3.2.4 Effect of concentration on electrospun polyacrylonitrile (PAN) nanofibres
- 3.2.5 Allometric Scaling Law between Average Polymer Molecular Weight and Electrospun Nanofibre Diameter
- 3.2.6 Effect of voltage on morphology and diameter of electrospun nanofibres
- 3.2.7 Enlarging Electrospinability by Nonionic Surfactants
- 3.3 Allometric Scaling Law for Static Fiction of Fibrous Materials
- 3.4 Allometric scaling in Biology
- 4. Application of Vibration Technology to Electrospinning
- 4.1 Effect of viscosity on diameter of electrospun fibre
- 4.2 Effect of Vibration on Viscosity
- 4.3 Application of vibration technology to polymer electrospinning
- 4.4 Effect of solution viscosity on mechanical characters of Electrospun Fibres
- 4.5 Carbon Nanotube Reinforced Polyacrylonitrile Nanofibres by Vibration-Electrospinning
- 5. Megnetio-electrospinning: Control of the instability
- 5.1 Critical Length of Straight Jet in Electrospinning
- 5.2 Controlling Stability by Magnetic Field
- 5.3 Controlling Stability by Temperature
- 5.4 Siro-electrospinning
- 6. BioMimic Fabrication of Electrospun Nanofibres with High-throughput
- 6.1 Spider-spinning
- 6.2 Electrospinning of silk fibroin nanofibres
- 6.3 Mystery in spider-spinning process
- 6.4 Bubble-electrospinning
- 7. Controlling Numbers and Sizes of Beads in Electrospun nanofibres
- 7.1 Experiment Observation
- 7.2 Effects of different solvents
- 7.3 Effect of the polymer concentration
- 7.4 Effect of salt additive
- 8. Electrospun Nanoporous Microspheres for Nanotechnology
- 8.1 Electrospun nanoporous spheres with Chinese drug
- 8.2 Electrospinning-dilation
- 8.3 Single Nanoporous Fibre by Electrospinning
- 8.4 Micro sphere with nano-porosity
- 8.5 Micro-composite fibres by electrospinning
- 9. Super-carbon Nanotubes: An E-infinity Approach
- 9.1 E-infinity Nanotechnology
- 9.2 Application of E-Infinity to Electrospinning
- 9.3 Super-carbon Nanotubes: An E-infinity Approach
- 10. Mechanics in Nano-textile Science
- 10.1 Jet-vortex spinning and Cyclone model
- 10.2 Two-phase flow of Yarn Motion in High Speed Air and Micropolar Model
- 10.3 Mathematical Model for Yarn motion in Tube
- 10.4 Nano-hydrodynamics
- 10.5 A New Resistance Formulation for Carbon Nanotubes and Nerve Fibres
- 10.6 Differential-difference Model for Nanotechnology
- 11. Nonlinear Dynamics in Sirofil/Sirospun Yarn Spinning
- 11.1 Convergent point
- 11.2 Linear Dynamical Model
- 11.3 Nonlinear Dynamical Model
- 11.4 Stable Working Condition for Three-strand Yarn Spinning
- 11.5 Nano-sirospinning
Research assistance
We can help you find what you need. Call us or write us: Need help in your search?
US: 800.298.5699
Int'l: +1.240.747.3093
Related Markets
Nanotechnology Materials & Applications Reports