Disclosed is a method for preparation and activation of a super hydrophobic electret nanofibrous filter material for cleaning PM2.5, comprising the steps as follows: (1) dissolving polymer powders and resin into a corresponding solvent so as to prepare a polymer solution, then stirring on a magnetic stirrer and standing for use; (2) in order to reinforce the electrostatic effect of the fiber, before preparing the polymer solution, adding in organic electret nanoparticles into the solvent, then oscillating with an ultrasonic oscillator; (3) in order to reinforce the super hydrophobic effect of the filter, spraying a low surface energy solution on the prepared nanofiber with a designed nozzle to carry out modification.

The present disclosure relates to emulsions, methods of preparation thereof, and uses of said emulsions to fabricate porous polymeric microspheres as microcarriers for cell culture. In particular, the present disclosure relates to an emulsion with enhanced stability, characterized in that the emulsion comprises a) a water phase, the water phase is an aqueous solution comprising a salt; and b) an oil phase, the oil phase comprising a polymer; wherein the oil phase is immiscible with the water phase, and wherein the density differential of the water phase and oil phase is less than about 0.02 g/cm3. In a preferred embodiment, the polymer is polycaprolactone (PCL).

A non-flammable contact adhesive includes copolymer rubbers, tackifiers, stabilizer resins, and a solvent composed of a mixture of flammable and non-flammable components.

Methods for forming polymeric particles with a predetermined, controlled morphology, and methods for tuning the topology of polymeric particles through modification of components utilized in the formation process are described. An emulsion/condensation technique is used, including a first emulsifier in the aqueous phase and an organic phase that includes first and second solvents, a second emulsifier, and a polymer. The polymer is more soluble in the first solvent than the second solvent, and the second emulsifier is more soluble in the second solvent than the first solvent. Through modification of the relative amounts of the emulsifiers and solvents, particles with either smooth or rough surfaces can be formed. Particles are particularly useful as drug depots with controlled-release profiles.

A method of forming an acid-doped polyaniline (emeraldine salt) (PANi-ES) solution including steps of: (i) mixing polyaniline (emeraldine base) (PANi-EB) with a PANi-EB solvent and a gel-inhibitor to form a gel-inhibited PANi-EB solution; (ii) removing the gel-inhibitor from the gel-inhibited PANi-EB solution to form a PANi-EB solution; and (iii) adding an acid dopant to the PANi-EB solution to form a PANi-ES solution.

A soft body robotic device includes a body made at least partly from a polylactic-acid-based material, and a magnetic movement mechanism connected to the body. The magnetic movement mechanism is configured to support movement of the soft body robotic device and to interact with an external magnetic control device for movement of the soft body robotic device.

A method, i.e., trapping of structural coloration (TOSC), for fabricating solid 3D network-structured photonic crystals featuring tunable visible structural colorations includes the steps: a PS-PVP copolymer is dissolved in a chloride-containing solvent and is cast as an initial film, the copolymer self-assembles into 3D periodic network-structured morphology; the copolymer in the initial film is swollen in a polar solvent to form a solvated film; the solvated film is dried to form a solid photonic crystal. During evaporation of the polar solvent, the PVP blocks of the copolymer become glassy and form a thin glassy layer on the surface of the solvated film such that the 3D network structures of the copolymer in solvated state can be preserved into the solid photonic crystal revealing the similar periodicity and dimension to that in solvated state, which is very distinct from the film having 1D lamellar structure.

A method, i.e., trapping of structural coloration (TOSC), for fabricating solid 3D network-structured photonic crystals featuring tunable visible structural colorations includes the steps: a PS-PVP copolymer is dissolved in a chloride-containing solvent and is cast as an initial film, the copolymer self-assembles into 3D periodic network-structured morphology; the copolymer in the initial film is swollen in a polar solvent to form a solvated film; the solvated film is dried to form a solid photonic crystal. During evaporation of the polar solvent, the PVP blocks of the copolymer become glassy and form a thin glassy layer on the surface of the solvated film such that the 3D network structures of the copolymer in solvated state can be preserved into the solid photonic crystal revealing the similar periodicity and dimension to that in solvated state, which is very distinct from the film having 1D lamellar structure.

Method for applying an active component comprising providing a composition comprising: (a) at least one active component selected from a lubricating agent, an insecticidal agent, and an herbicidal agent; and (b) a carrier in an amount effective to solvate or emulsify said active component, said carrier comprising a monochlorotrifluoropropene; and removing the carrier from the composition.

A method of preparing a partially crystalline polycarbonate powder, including: dissolving an amorphous polycarbonate in a halogenated alkane solvent to form a solution; combining the solution with a crystallizing non-solvent that is miscible with the halogenated alkane solvent, under high shear mixing conditions effective to form a partially crystalline polycarbonate precipitate having a D90 particle size of less than 150 micrometers; an average particle diameter of less than or equal to 100 micrometers, or an average particle diameter of 0 to 100 micrometers; and at least 20% crystallinity, or at least 25% crystallinity, or 25 to 35% crystallinity.