A liquid colorant for use in molding or extruding plastic products comprises pigment dispersed in cottonseed oil.

The present invention relates to processes for making compatibilized high aspect ratio barrier additives and polymer compositions that comprise compatibilized high aspect ratio barrier additives. The invention also relates to compositions produced by these processes, and articles formed from polymer compositions of this invention. The barrier additives provide passive barriers to gas molecules such as oxygen and carbon dioxide minimizing transit of such molecules through sidewalls of polymer articles containing the barrier additives.

A process for producing a non-tobacco plant composition and a process for producing an electronic cigarette filler to be used for an electronic cigarette using a non-tobacco plant are provided with which cooling sensation of menthol can be enjoyed, capable of keeping menthol flavor even after long-term storage. A process for producing a non-tobacco plant composition includes a menthol-dissolving step of preliminarily mixing menthol, a lower alcohol and a water-insoluble crosslinked polymer to obtain a menthol-dissolved product, and a mixing step of mixing a non-tobacco plant, an aerosol former and the menthol-dissolved product obtained by the menthol-dissolving step.

Methods for recycling thermoset polymers, particularly by changing them into dynamic networks with the use of an appropriate catalyst solution which transforms the thermoset polymer into a vitrimer-like composition. The methods include the step of swelling a crosslinked thermoset polymer in a solution including a catalyst, whereby the catalyst diffuses into the thermoset polymer, in particular into the thermoset network. Upon removal of the liquid portion of the solution, such as solvent, the catalyst facilitates the occurrence of exchange reactions at elevated temperatures, rendering the system a dynamic network. The vitrimerized composition having the thermoset polymer and catalyst is recyclable and processable and thus suitable for many end uses.

Provided are processes for making a polymer composition comprising (i) providing a multistage polymer latex by emulsion polymerization in the presence of a phosphate surfactant, wherein the multistage polymer comprises (a) a first stage polymer having a T.sub.g of 20 C. or lower, and (b) a final stage polymer having a T.sub.g of 50 C. or higher, (ii) coagulating the multistage polymer latex, (iii) treating the coagulated multistage polymer with an alkaline phosphate, (iv) drying the coagulated multistage polymer to a water content of less than 1 weight % based on the dry weight of the multistage polymer, wherein the weight of the dried multistage polymer comprises 100 ppm or more, based on the dry weight of the multistage polymer, of phosphorous that is in the form of an alkaline phosphate. Also provided are processes for making matrix resin compositions comprising such polymer compositions and a matrix resin.

Water soluble particles can be incorporated into articles that are produced from a polymer based matrix with reduced appearance implications. Using a specific formulation including a water permeable polymer, water soluble particles and a surfactant, and a specific process for combining these components, agglomeration of the particles can be reduced. This is particularly useful for applications where the particles are incorporated into packaging films and extracted upon exposure to moist products.

This invention relates to a composition which is suitable for use in the vulcanization of the rubber. The composition is a non-aqueous water soluble polymer based composition comprising a cationic silicate component. The composition may further include a second cationic additive component which is desirable in a rubber vulcanization process. The invention further relates to a method for preparing these compositions.

The present disclosure relates to a process for dyeing a hydrolysis-resistant polyester film. The process comprises dyeing of a hydrolysis resistant polyester film in a dye bath comprising at least one coloring agent (dye), at least one polyhydric alcohol, and optionally at least one UV absorber to obtain a dyed film. The dyed film is subjected to quenching followed by cleaning and drying to obtain a dyed hydrolysis-resistant polyester film. The process of the present disclosure is simple, economical, improve hydrolysis resistance, and also retains the mechanical properties of the film when exposed to harsh environmental conditions.

A rubber composition contains: at least one rubber component selected from the group consisting of an ethylene propylene diene rubber, a chloroprene rubber, a nitrile rubber, and an acrylic rubber; 1.5 to 30 parts by mass of a fluorene-modified cellulose nanofiber per 100 parts by mass of the rubber component; and 30 to 120 parts by mass of a carbon-based filler per 100 parts by mass of the rubber component. A method of producing a rubber composition comprises: kneading a dispersion of a fluorene-modified cellulose nanofiber in a process oil and a rubber component to prepare a kneaded material; and mixing a vulcanizing agent into the kneaded material.

Disclosed are a graphene composite fiber and a manufacturing method thereof. The manufacturing method of the graphene composite fiber of the present disclosure includes a first solution preparation step of preparing a first solution by dispersing graphene in a dispersion solvent, a second solution preparation step of preparing a second solution by adding a polymer to the first solution, a graphene master chip preparation step of preparing a plurality of graphene master chips by solidifying and then cutting the second solution, and a graphene composite fiber preparation step of preparing a graphene composite fiber by spinning the plurality of graphene master chips and the polymer by a fiber spinning device.