A polylactic acid fiber is provided. The polylactic acid fiber includes a first polylactic acid material and a second polylactic acid material. The first polylactic acid material is encapsulated by the second polylactic acid material. Based on a total volume of the polylactic acid fiber being 100%, a volume of the second polylactic acid material is at least 20%. The second polylactic acid material includes 15 wt % to 85 wt % of poly(D-lactic acid) and 15 wt % to 85 wt % of poly(L-lactic acid).

In a first embodiment, a coal treatment process includes exposing a material comprising coal to ionic liquid(s) to form a first mixture, isolating a residue from the first mixture, forming a second mixture comprising the residue, and electrospinning the second mixture to form a carbon fiber precursor material. In a second embodiment, a coal treatment process includes exposing a material comprising coal to ionic liquid(s) to form a mixture comprising solids and a liquid fraction, separating and filtering the liquid fraction from the mixture, and isolating one or more compounds from the liquid fraction. In a third embodiment, a coal treatment process includes exposing a material comprising coal to ionic liquid(s) to form a first mixture comprising residues, exposing the first mixture to (a) an acid, (b) a solvent, or (c) both to form a second mixture, and isolating rare earth elements and rare earth element compounds.

The invention relates to a system for manufacturing by electrospinning a composite fibre structure; wherein the system comprises a first device of solution electrospinning comprising a first head biased to a first voltage, a second device of melt electrospinning comprising a second head electrically connected to ground, and a moveable collector configured to be either electrically connected to ground or biased to a second voltage. Wherein the system further comprises switching means configured to selectively assign the electrical status of the collector.

A sheet of substrate (7) travels along a first path in a first direction between a first collecting electrode (1) and a second spinning wire electrode (2); and the second spinning wire electrode (2) travels in a second direction (10) approximately perpendicular to the first direction at an approximately constant operational distance to the sheet of substrate (7). One or more secondary guiding means (4) guide the second spinning wire electrode (2) in a third direction at least partly parallel to the first direction i.e. parallel to the traveling direction of the sheet of substrate, and tertiary guiding means (5) guide the second spinning wire electrode (2) in a fourth direction (11) approximately perpendicular to the first direction and parallel but opposite the second direction (10) at a constant operational distance to the sheet of substrate (7).

The present disclosure discloses a high-whiteness polyimide microfiber and a preparation method thereof and use. The polyimide fiber includes polyimide obtained from the reaction of wholly alicyclic dianhydride HTDA and an aromatic diamine monomer containing methyl or trifluoromethyl by chemical imidization. In the present disclosure, the polyimide microfiber has both excellent heat-resistant stability and spinning film-forming property, and the fabric has ultra-high whiteness. The microfiber fabric prepared from the polyimide fiber may be used as a component with high-temperature resistant and high-whiteness in personal protective equipment such as mask and protective clothing, and also may be used as an electronic component in the high-tech field such as aerospace, optoelectronic, microelectronic and automobile.

A nanofiber for an air filter and a method for manufacturing the same are proposed. The nanofiber may include a styrene-(meth)acrylate-acrylonitrile random copolymer having a zwitterionic functional group in a side chain. The nanofiber can greatly enhance the bonding of particulate matter (PM) particles with the surface of a polymer by having a high dipole moment derived from the zwitterionic functional group, thereby providing high efficiency of filtration (>99.9%) of the PM particles. Furthermore, the nanofiber can be very usefully used as a core material for air purifier filters and vehicle air purification filters by having low airflow resistance and excellent antibacterial properties.

A method for the production of conductive structures, wherein nanofibers are applied with a photocatalytic component onto a substrate, in particular by electrospinning, and wherein a metallic layer is deposited photolytically on the substrate.

Disclosed herein is a multicellular lay-up process. The process comprises the steps of: a) forming a core material, b) forming a capsule material, c) encapsulating the core with the capsule material, d) adding the capsule to a substrate, and e) exposing the capsule to at least one bioactivating agent.

Disclosed is a biocomposite product with high microbial activity obtained by using bee bread, the method of obtaining this product and using of this biocomposite material for the coating of products like artificial materials, packaging, etc. to be used in areas requiring hygiene or their use as an intermediate raw material.

The present invention provides a method for fabricating patterned cellulose nanocrystal (CNC) composite nanofibers and thin films for optical and electromagnetic sensor and actuator application, comprising the following steps of: selecting materials for fabricating patterned cellulose nanocrystal (CNC) composite nanofibers; and fabricating patterned CNCs composite nanofibers by incorporating secondary phases either during electrospinning or post-processing, wherein the secondary phases may include dielectrics, electrically or magnetically activated nanoparticles or polymers and biological cells mechanically reinforced by CNCs.