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Applications of Polymer Nanofibers


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yarn using two opposite asymmetric nozzles. Fibers and Polymers 15 (12): 2535–2540.

      13 Fedorova, N. and Pourdeyhimi, B. (2007). High strength nylon micro‐ and nanofiber based nonwovens via spunbonding. Journal of Applied Polymer Science 104 (5): 3434–3442.

      14 Feng, J. (2017). Preparation and properties of poly(lactic acid) fiber melt blown non‐woven disordered mats. Materials Letters 189: 180–183.

      15 Ge, Y., Zhu, J., Dirican, M. et al. (2017). Fabrication and electrochemical behavior study of nano‐fibrous sodium titanate composite. Materials Letters 188: 176–179.

      16 Gheibi, A., Latifi, M., Merati, A.A., and Bagherzadeh, R. (2014). Piezoelectric electrospun nanofibrous materials for self‐powering wearable electronic textiles applications. Journal of Polymer Research 21 (7): 469–475.

      17 Gibson, P., Schreuder‐Gibson, H., and Rivin, D. (2001). Transport properties of porous membranes based on electrospun nanofibers. Colloids and Surfaces A: Physicochemical and Engineering Aspects 187: 469–481.

      18 Gimenez‐Lopez, M.D.C., La Torre, A., Fay, M.W. et al. (2013). Assembly and magnetic bistability of Mn3O4 nanoparticles encapsulated in hollow carbon nanofibers. Angewandte Chemie International Edition 52 (7): 2051–2054.

      19 Gorjanc, M., Bukošek, V., and Gorenšek, M. (2009). The influence of water vapor plasma treatment on specific properties of bleached and mercerized cotton fabric. Textile Research Journal 80 (6): 557–567.

      20 Han, X.J., Huang, Z.M., He, C.L. et al. (2006). Coaxial electrospinning of PC (shell)/PU (core) composite nanofibers for textile application. Polymer Composites 27 (4): 381–387.

      21 Han, F., Liu, S., Liu, X. et al. (2014). Woven silk fabric‐reinforced silk nanofibrous scaffolds for regenerating load‐bearing soft tissues. Acta Biomaterialia 10 (2): 921–930.

      22 Hassan, M.A., Yeom, B.Y., Wilkie, A. et al. (2013). Fabrication of nanofiber meltblown membranes and their filtration properties. Journal of Membrane Science 427: 336–344.

      23 He, J., Zhou, Y., Qi, K. et al. (2013). Continuous twisted nanofiber yarns fabricated by double conjugate electrospinning. Fibers and Polymers 14 (11): 1857–1863.

      24 He, J., Qi, K., Wang, L. et al. (2015). Combined application of multinozzle air‐jet electrospinning and airflow twisting for the efficient preparation of continuous twisted nanofiber yarn. Fibers and Polymers 16 (6): 1319–1326.

      25 Hou, T., Li, X., Lu, Y., and Yang, B. (2017). Highly porous fibers prepared by centrifugal spinning. Materials and Design 114: 303–311.

      26 Jiang, G. and Qin, X. (2014). An improved free surface electrospinning for high throughput manufacturing of core‐shell nanofibers. Materials Letters 128: 259–262.

      27 Jiang, G., Sai, Z., and Qin, X. (2013). High throughput of quality nanofibers via one stepped pyramid‐shaped spinneret. Materials Letters 106: 56–58.

      28 Jiang, H., Ge, Y., Fu, K. et al. (2015). Centrifugally‐spun tin‐containing carbon nanofibers as anode material for lithium‐ion batteries. Journal of Materials Science 50 (3): 1094–1102.

      29 Kanafchian, M., Valizadeh, M., and Haghi, A.K. (2011). Fabrication of nanostructured and multicompartmental fabrics based on electrospun nanofibers. Korean Journal of Chemical Engineering 28 (3): 763–769.

      30 Kwon, I.K. and Matsuda, T. (2005). Co‐electrospun nanofiber fabrics of poly(l‐lactide‐ɛ‐caprolactone) with type I collagen or heparin. Biomacromolecules 6 (4): 2096–2105.

      31 Laforgue, A. (2011). All‐textile flexible supercapacitors using electrospun poly(3,4‐ethylenedioxythiophene) nanofibers. Journal of Power Sources 196 (1): 559–564.

      32 Lee, S. and Obendorf, S.K. (2007a). Use of electrospun nanofiber web for protective textile materials as barriers to liquid penetration. Textile Research Journal 77 (9): 696–702.

      33 Lee, S. and Obendorf, S.K. (2007b). Transport properties of layered fabric systems based on electrospun nanofibers. Fibers and Polymers 8 (5): 501–506.

      34 Lee, Y., Kim, B.S., Hong, J.H. et al. (2012). Enhanced mechanical properties and pre‐tension effects of polyurethane (Pu) nanofiber filaments prepared by electrospinning and dry twisting. Journal of Polymer Research 19 (2): 9774–9778.

      35 Li, X. and Gong, Y. (2015). Design of polymeric nanofiber gauze mask to prevent inhaling PM2.5 particles from haze pollution. Journal of Chemistry 2015: 1–5.

      36 Liu, Y., Huang, K., Fan, Y. et al. (2013). Binder‐free Si nanoparticles@carbon nanofiber fabric as energy storage material. Electrochimica Acta 102: 246–251.

      37 Lu, Y., Fu, K., Zhang, S. et al. (2015). Centrifugal spinning: a novel approach to fabricate porous carbon fibers as binder‐free electrodes for electric double‐layer capacitors. Journal of Power Sources 273: 502–510.

      38 Marano, S., Barker, S.A., Raimi‐Abraham, B.T. et al. (2016). Development of micro‐fibrous solid dispersions of poorly water‐soluble drugs in sucrose using temperature‐controlled centrifugal spinning. European Journal of Pharmaceutics and Biopharmaceutics 103: 84–94.

      39 Matsumoto, H., Yako, H., Minagawa, M., and Tanioka, A. (2007). Characterization of chitosan nanofiber fabric by electrospray deposition: electrokinetic and adsorption behavior. Journal of Colloid and Interface Science 310 (2): 678–681.

      40 McEachin, Z. and Lozano, K. (2012). Production and characterization of polycaprolactone nanofibers via forcespinning™ technology. Journal of Applied Polymer Science 126: 473–479.

      41 Park, J.A. and Kim, S.B. (2017). Antimicrobial filtration with electrospun poly(vinyl alcohol) nanofibers containing benzyl triethylammonium chloride: immersion, leaching, toxicity, and filtration tests. Chemosphere 167: 469–477.

      42 Park, S.J., Lee, B.K., Na, M.H., and Kim, D.S. (2013). Melt‐spun shaped fibers with enhanced surface effects: fiber fabrication, characterization and application to woven scaffolds. Acta Biomaterialia 9 (8): 7719–7726.

      43 Park, M., Lee, K.S., Shim, J. et al. (2016). Environment friendly, transparent nanofiber textiles consolidated with high efficiency PLEDs for wearable electronics. Organic Electronics 36: 89–96.

      44 Qin, X.H. and Xin, D.P. (2010). The study on the air volume fraction of electrospun nanofiber nonwoven mats. Fibers and Polymers 11 (4): 632–637.

      45 Rajgarhia, S.S., Benavides, R.E., and Jana, S.C. (2016). Morphology control of bi‐component polymer nanofibers produced by gas jet process. Polymer 93: 142–151.

      46 Safranskia, D.L., Boothby, J.M., Kelly, C.N. et al. (2016). Thermo‐mechanical behavior and structure of melt blown shape‐memory polyurethane nonwovens. Journal of Mechanical Behavior of Biomedical Materials 62 (2016): 545–555.

      47 Shang, M., Wang, W., Yin, W. et al. (2010). General strategy for a large‐scale fabric with branched nanofiber‐nanorod hierarchical heterostructure: controllable synthesis and applications. Chemistry A European Journal 16 (37): 11412–11419.

      48 Shao, W., He, J., Han, Q. et al. (2016). A biomimetic multilayer nanofiber fabric fabricated by electrospinning and textile technology from polylactic acid and tussah silk fibroin as a scaffold for bone tissue engineering. Materials Science Engineering C 67: 599–610.

      49 Shi, Q., Vitchuli, N., Ji, L. et al. (2011). A facile approach to fabricate porous nylon 6 nanofibers using silica nanotemplate. Journal of Applied Polymer Science 120 (1): 425–433.

      50 Smit, E., Bűttner, U., and Sanderson, R.D. (2005). Continuous yarns from electrospun fibers. Polymer 46 (8): 2419–2423.

      51 Su, C.I., Lai, T.C., Lu, C.H. et al. (2013). Yarn formation of nanofibers prepared using electrospinning. Fibers and Polymers 14 (4): 542–549.

      52 Su, C.I., Lu, C.H., Wong, J.W., and Liu, Y.S. (2014). The optimal continuous manufacturing conditions for oxidized PAN nanofiber nonwovens. Fibers and Polymers 15 (9): 1822–1827.

      53 Sugawara, K., Ikaga, T., Kim, K.H. et al. (2015). Fiber structure development in PS/PET sea‐island conjugated fiber during continuous laser drawing.