Characterization of Polymers and Fibers The Textile Institute Book Series
Auteurs : Singh Mukesh Kumar, Singh Annika
Characterization of Polymers and Fibres addresses an integral part of fiber and polymer manufacturing processes that is crucial in helping manufacturers ensure that final products achieve intended specifications. The characterization of fiber and polymers is needed for attributes including molecular weight, morphology, dyeing behavior, tensile, optical and thermal behavior. This book covers a wide range of characterization techniques, including thermal, X-ray diffraction, solubility, tensile, optical, hygroscopic and particle size distribution. Introductions and definitions are provided where beneficial to make topics accessible to a broad range of readers in both academia and industry.
Addressing advances from the fields of bioscience, polymer science, material science, and textile science, this book is wide in scope, drawing on the latest research to provide details of characterization techniques and equipment.
1. Polymers 2. Fibre Extrusion by Melt Spinning 3. Spin Finish for Natural and Synthetic Fibres 4. Solution Spinning: Dry spinning 5. Regenerated Fibres 6. Fibre Characterization 7. Fibre Drawing and Crystallization 8. Polymer and Fibre Characterization by X-Ray diffraction 9. Annealing (Heat setting) of fibres 10. Overall Orientation of Textile Fibres Sonic Modulus and Birefringence 11. Texturing of Textile Fibres and Yarns 12. Tow-to Top Conversion of Textile Filaments 13. Thermal Characterization of Materials by Differential Scanning Calorimeter (DSC) 14. Thermal Characterization of Natural and Synthetic Fibres by Thermogravemetric Analyser (TGA) 15. Dynamic Modulus Analysis 16. Bicomponent Fibres 17. FTIR Analysis of Natural and Synthetic Fibres 18. Nuclear Magnetic Resonance Spectroscopy of Natural and Synthetic Fibres 19. Particle Size Analysis 20. Contact Angle and Surface Wettability Measurement 21. Scanning Electron Microscope 22. Inductively Coupled Plasma-Atomic Emission Spectrometry (ICP-AES) 23. Transmission Electron Microscope 24. Atomic Force Microscopy
Annika Singh is Assistant Professor of Bio-technology at the CSJMU, Kanpur, and was previously a Researcher at IIT Delhi, and Indian Institute of Pulse Researches, Kanpur. Her research experience is focused on biopolymer characterization.
- Provides a thorough description of the material quality control process, including the latest industry practice
- Presents material characterization at all levels, from the atomic level to surface structure
- Covers technical advice on natural fiber characterization methods, including XRD, XPS, TGA, SEM, TEM, AFM, Contact angle, Particle size analysis, FTIR, and NMR
Date de parution : 09-2021
Ouvrage de 506 p.
15x22.8 cm
Thèmes de Characterization of Polymers and Fibers :
Mots-clés :
?Absorption contrast; Absorption technique; Aerosols; Aging; Auger electrons; Backscattered electrons; Bicomponent fiber; Bicomponent fibers; Bone cement; Bragg plane; Burning test; Calorimetry; Cantilever deflection; Cathodoluminescence scattering; Cellulose triacetate; Chemical mapping; Chord length; Coagulation; Coagulation bath; Coaxial electrospinning; Coflowing; Combustion; Comonomers; Configuration; Conformation; Conjugate fibers; Constructive interference; Contact angle; Critical point drying; Crystalline orientation; Crystallinity; Cyclic loading; Degradation; Degree of polymerization; Derivative curve; Detector; Detectors; Deuterated triglycine sulfate; Diameter equivalent; Diffraction; Diffraction contrast; Diffusion; Diffusion rate; Dynamic light scattering; Dynamic mechanical analysis; Elastic scattering; Electromagnetic lens; Electron column; Electron gun; Electrospinning; Emulsification; Emulsion; Equivalent sphere; Evaporation rate; Fiber identification; Fiber microscopy; Fiber spectroscopy; Field emission electron gun; Fingerprint region spectrometer; Finish on yarn; Flame atomic emission spectroscopy; Fluorochemicals; Gel-spinning; Glass transition; Heat capacity; Heat-flux; Hydraulic drag; Image analysis; Infrared beam; Infrared spectrum; Interatomic potential; Interference; Interferogram signal; Lamellar Grating; Laser diode; Lattice; Loss tangent; Lyocell; Man-made fibers; Melt flow index; Melt spinning; Microfluidics; Microwave-induced plasma; Miller indices; Monochromator; Morphological imaging; Natural fibers; Nebulizer; Nuclear magnetic resonance; Nuclei; Null balance; Offset of degradation; Oil pickup (OPU); Oil repellency; Onset of degradation; Onset of melting; Overall orientation; Particle size distribution; Phase difference; Phase imaging