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2008, 1st ed., ISBN 9780471790594, xix, 403
Discover new and emerging applications of polymer nanofibers alongside the basic underlying science and technology... 
Electrospinning | Synthetic products | Nanofibers | Polymers | Industrial chemistry & manufacturing technologies | Technology & Engineering | Chemical & Biochemical
Book
Polymer (Guilford), ISSN 0032-3861, 2008, Volume 49, Issue 10, pp. 2387 - 2425
In electrospinning, polymer nanofibers are formed by the creation and elongation of an electrified fluid jet... 
Encapsulation | Viscosity | Ribbons | Envelope cone | Electrical bending instability | Silk nanofibers | Carbon nanotubes | Carbon nanofibers | Charge transport | Metal | Protein preservation | Straight segment | Electrodes | Doppler velocimeter | Polymer melts | Fuel cells | Buckling | Hierarchical structures | Branching | Glints | Taylor cone | Meniscus | Coated nanofibers | Exfoliated clay | Conglutination | Metal nanofibers | Instabilities of jets | Interference colors | Polymer fluids | Tapered segment | Thermophotovoltaic device | Non-Newtonian fluids | Structures in interplanetary space | Drop | Solidification | Droplet shape | Polymer solutions | Spider silk | Molten polymers | Jet | Collection | Ceramic | Beads | encapsulation | envelope cone | buckling | conglutination | solidification | hierarchical structures | spider silk | branching | non-Newtonian fluids | FIBERS | polymer melts | jet | beads | electrical bending instability | metal nanofibers | BENDING INSTABILITY | ribbons | polymer solutions | electrodes | meniscus | metal | instabilities of jets | exfoliated clay | collection | carbon nanofibers | charge transport | glints | PLANE | drop | ceramic | structures in interplanetary space | SHAPES | coated nanofibers | DROPLETS | polymer fluids | straight segment | carbon nanotubes | fuel cells | interference colors | silk nanofibers | molten polymers | POLYMER SCIENCE | thernmphotovoltaic device | droplet shape | viscosity | protein preservation | tapered segment | Proteins | Polymer industry
Journal Article
Journal of the American Chemical Society, ISSN 0002-7863, 04/2004, Volume 126, Issue 14, pp. 4502 - 4503
Seeding a conventional chemical oxidative polymerization of aniline with even very small amounts of biological, inorganic, or organic nanofibers (usually <1... 
CHEMISTRY, MULTIDISCIPLINARY | NANOSTRUCTURES | Microscopy, Electron, Scanning | Aniline Compounds - chemistry | Nanotechnology - methods | Nanotubes, Carbon - chemistry | Aniline Compounds - chemical synthesis
Journal Article
Angewandte Chemie (International ed.), ISSN 1433-7851, 2017, Volume 56, Issue 39, pp. 11744 - 11748
Journal Article
Journal of applied polymer science, ISSN 1097-4628, 2005, Volume 96, Issue 2, pp. 557 - 569
.... Nanofibers, due to their high surface area and porosity, find applications as filter medium, adsorption layers in protective clothing, etc... 
polymer | nanotechnology | collagen | fiber | polyester | Polymer | Polyester | Collagen | Nanotechnology | Fiber | POLYMER SCIENCE | ACID | FIBERS | DIAMETER | JET | BENDING INSTABILITY | MORPHOLOGY | LIQUIDS
Journal Article
Materials Science and Engineering: C, ISSN 0928-4931, 2017, Volume 76, pp. 1413 - 1423
Electrospinning has been widely used as a nanofiber fabrication technique. Its simple process, cost effectiveness and versatility have appealed to materials scientists globally... 
MATS | FIBROUS MATERIALS | MATERIALS SCIENCE, BIOMATERIALS | POLYELECTROLYTE COMPLEX | ACID | COMPOSITE NANOFIBERS | ANTIBACTERIAL ACTIVITY | CHITOSAN | DRUG-RELEASE | CELLULOSE-ACETATE | FABRICATION | Wound Healing | Nanofibers | Polymers | Humans | Drug Delivery Systems | Tissue Engineering | Drugs | Drug delivery systems | Tissue engineering | Vehicles
Journal Article
Chemical Society reviews, ISSN 1460-4744, 2017, Volume 46, Issue 5, pp. 1510 - 1525
.... Polyaniline nanofibers, on the other hand, have demonstrated, through manufacturing techniques discovered during the past decade, increased processability, higher surface area, and improved... 
THIN-FILMS | SENSITIZED SOLAR-CELLS | ELECTRODE MATERIAL | ELECTRICAL-PROPERTIES | SELF-DOPED POLYANILINE | CORROSION PROTECTION | GAS SENSORS | ELECTROCHROMIC DEVICES | CHEMISTRY, MULTIDISCIPLINARY | HIGH-PERFORMANCE SUPERCAPACITOR | ULTRAFILTRATION MEMBRANE | Conducting polymers | Morphology | Consistency | Dispersions | Nanofibers | Surface area | Surface stability | Polyanilines
Journal Article