A process of forming a lactide copolymer includes forming a dimethylidene lactide molecule from an L-lactide molecule. The process also includes forming a functionalized lactide monomer from the dimethylidene lactide molecule. The process includes forming a mixture that includes the functionalized lactide monomer and a bisphenol A (BPA) monomer or a BPA-derived monomer. The process further includes polymerizing the mixture to form a lactide copolymer.

This epoxy resin composition contains an epoxy resin (A) having at least three glycidyl groups in the molecule, an epoxy resin (B) having at least one sulfur atom in the molecule, and an imidazole compound (C) containing at least one of 2-phenyl-4,5-dihydroxymethyl imidazole and 2-phenyl-4-methyl-5-hydroxymethyl imidazole.

A coating method for a cationic electrodeposition coating material includes steps for immersing a metal object to be coated in a first solution bath, a second solution bath and a third solution bath, and wherein: at least one step among the three steps is cationic electrodeposition coating that is accompanied by application of a current; a coating film which is formed through the three steps contains at least a base resin component (A), a reaction component (B) and a catalyst (C); and the first solution bath, the second solution bath and the third solution bath contain one or a combination of two of the base resin component (A), the reaction component (B) and the catalyst (C).

Disclosed is a composition and use thereof for the recovery of hydrocarbon fluids from a subterranean reservoir. More particularly, this invention concerns sulfonated epoxy resin polymers comprising an epoxide-containing compound, a primary amino sulfonate, and optionally one or more of a primary monoamine alkylene oxide oligomer, that modify the permeability of subterranean formations and increase the mobilization and/or recovery rate of hydrocarbon fluids present in the formations.

The present invention provides a compound represented by the general formula (I), and a polymerizable composition containing the compound. When the polymerizable composition containing the compound represented by the formula (I) is used to form a filmy product, the resulting filmy product exhibits less change over time in phase difference and reverse wavelength dispersion and when the filmy polymer is irradiated with UV light, peeling from a substrate is unlikely to be caused. Further, the invention provides a polymer obtained through polymerization of the polymerizable composition and an optically anisotropic body obtained using the polymer.

Solvent free epoxy system that includes: a hardener compound H comprising: a molecular structure (Y.sup.1R.sub.1Y.sup.2), wherein R.sub.1 is an ionic moiety Y.sup.1 is a nucleophilic group and Y.sup.2 nucleophilic group; and an ionic moiety A acting as a counter ion to R.sub.1; and an epoxy compound E comprising: a molecular structure (Z.sup.1R.sub.2Z.sup.2), wherein R.sub.1 is an ionic moiety, Z.sup.1 comprises an epoxide group, and Z.sup.2 comprises an epoxide group; and an ionic moiety B acting as a counter ion to R.sub.2. In embodiments, the epoxy compound E and/or the hardener H is comprised in a solvent-less ionic liquid. The systems can further include accelerators, crosslinkers, plasticizers, inhibitors, ionic hydrophobic and/or super-hydrophobic compounds, ionic hydrophilic compounds, ionic transitional hydrophobic/hydrophilic compounds, biological active compounds, and/or plasticizer compounds. Polymers made from the disclosed epoxy systems and their methods of used.

Provided is a resin composition that can provide a cured product of low dielectric tangent, high mechanical strength, and high adhesiveness. The resin composition contains (A) a resin having a thermosetting functional group FA, (B) a resin having a radical polymerizable functional group FB, and (C) a resin having a functional group FA reacting with the thermosetting functional group FA and a functional group FB reacting with the radical polymerizable functional group FB. A number n.sub.a of the functional group FA of the component (C) when the number of the thermosetting functional group FA of the component (A) is defined as 1 and a number n.sub.b of the functional group FB of the component (C) when the number of the radical polymerizable functional group FB of the component (B) is defined as 1 satisfy 0.01n.sub.a200 and 0.01n.sub.b400, respectively.

Provided is a thermosetting resin composition (C) of which curing can be started at a relatively low temperature in a short time and a cured product exhibits high heat resistance, the thermosetting resin composition (C) comprising an epoxy resin; an epoxy resin curing agent; and an epoxy resin curing accelerator, wherein the epoxy resin curing agent contains an imidazole-based curing agent 1 which is not encapsulated in a microcapsule and a curing agent 2 which is encapsulated in a microcapsule, and the epoxy resin curing accelerator comprises a urea derivative.

A process of forming a lactide copolymer includes forming a dimethylidene lactide molecule from an L-lactide molecule. The process also includes forming a functionalized lactide monomer from the dimethylidene lactide molecule. The process includes forming a mixture that includes the functionalized lactide monomer and a bisphenol A (BPA) monomer or a BPA-derived monomer. The process further includes polymerizing the mixture to form a lactide copolymer.

A polymerizable composition for an optical material according to the present invention includes one or two or more compounds selected from the group consisting of component (A): an ester compound having a specific structure and component (B): an ether compound having a specific structure, and a polymerizable compound.