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Supramolecular-based nanofibers
Materials Science and Engineering: C, 2019Supramolecular-based nanofibers, which successfully combine the unique properties of supramolecular interactions with the advantages of nanofibrous structure, are widely used in a variety of biomedical applications such as controlled drug delivery. Compared with traditional polymer nanofibers, supramolecular-based nanofibers can overcome the bottleneck
Yi, Wang +5 more
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Carbohydrate Polymers, 2018
A cellulose nanofiber board (CNF-board) with a nominal thickness of 3 mm was fabricated without adhesive or additive. To provide comparison, a cellulose fiber board (CF-board) was also fabricated. A novel cold pre-press apparatus was made to dewater highly absorbent CNF gel prior to drying.
Hossein, Yousefi +3 more
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A cellulose nanofiber board (CNF-board) with a nominal thickness of 3 mm was fabricated without adhesive or additive. To provide comparison, a cellulose fiber board (CF-board) was also fabricated. A novel cold pre-press apparatus was made to dewater highly absorbent CNF gel prior to drying.
Hossein, Yousefi +3 more
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Photoswitchable Organic Nanofibers
Advanced Materials, 2007A photoswitchable nanomaterial is presented, electrospun organic nanofibers based on 1',3'-dihydro-1',3',3'-trimethyl-6-nitrospiro [2H-1-benzopyran-2,2'-(2H)-indole]. The switching properties of the nanofibers were investigated by studying the evolution of absorbance with different UV exposure times, photoluminescence lifetime, cyclic ...
Di Benedetto F +5 more
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Glassy carbon nanofibers from electrospun cellulose nanofiber
Journal of Materials Science, 2014Glassy carbon nanofibers (g-CNFs) with diameter of ca. 45 nm were prepared from electrospun cellulose nanofibers (CelluNFs) by two sequential steps: stabilization and carbonization. The CelluNFs were stabilized at 400 °C and carbonized at 850 and 1400 °C to produce g-CNFs.
Yingying Liu +4 more
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2013
One of the promising new techniques in the production of biomaterials is the electrospinning process, whereby fibers of uniform thickness down to the nanoscale can be produced from solutions of polymeric material in a high electric field. At the same time there has been increasing interest in the manufacture of biodegradable nanomaterials from nonfood ...
Jeffrey E, Plowman +2 more
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One of the promising new techniques in the production of biomaterials is the electrospinning process, whereby fibers of uniform thickness down to the nanoscale can be produced from solutions of polymeric material in a high electric field. At the same time there has been increasing interest in the manufacture of biodegradable nanomaterials from nonfood ...
Jeffrey E, Plowman +2 more
openaire +2 more sources
Nanooptics Using Organic Nanofibers
2007The possibility to separate nanofibers from each other by distances that are larger than the wavelength of the emitted light allows one to investigate in detail the influence of morphological changes in the nanometer-range on the optical properties. As an example we show in Fig.
Rubahn, Horst-Günter +2 more
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Organic Crystalline Nanofibers
2008Organic crystalline nanofibers are a new class of nanoscaled organic materials that bear high potential as model systems for optics and photonics at the diffraction limit. In addition, due to the possibility to tailor to a large extent morphology as well as optoelectronic properties, organic nanofibers are promising elements for future integrated ...
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Characterization of nanofibers and nanofiber membranes
2023Morteza Afsari +2 more
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