Abstract: A coating composition, a method for coating a substrate and a pipeline are provided. The coating composition includes at least one epoxy resin and at least one functionalized elastomer. The functionalized elastomer includes an elastomer being grafted with acid anhydride-based groups. The method includes steps of applying the coating composition to the substrate, and curing the coating composition so as to obtain a coating. The pipeline includes a pipe and the coating formed from the coating composition coated on the pipe. The coating has improved flexibility, and improved heat and chemical resistance.

Abstract: A blanket for transferring a paste image from an engraved plate to a substrate is provided. The blanket includes a foam, a PET layer on the foam, and a paste transfer layer on the PET layer. The entire blanket has a Tan ? value of 0.05 to 0.10. The foam can be made of polyurethane, polyethylene, nitrile-butadiene rubber, silicone, or a combination thereof. The paste transfer layer can be made of silicone rubber, fluoro rubber, fluorosilicone rubber, a combination thereof, or a multi-layered structure thereof.

Abstract: A coating composition, a method for coating a substrate and a pipeline are provided. The coating composition includes at least one epoxy resin and at least one functionalized elastomer. The functionalized elastomer includes an elastomer being grafted with acid anhydride-based groups. The method includes steps of applying the coating composition to the substrate, and curing the coating composition so as to obtain a coating. The pipeline includes a pipe and the coating formed from the coating composition coated on the pipe. The coating has improved flexibility, and improved heat and chemical resistance.

Abstract: A curable resin composition, an article, and a method for fabricating the same are provided. The curable resin composition includes an epoxy resin; an anhydride; and a catalyst. In particular, the catalyst includes an imidazole and an organic metal compound, and the organic metal compound includes an organic tin compound, organic zinc compound, organic nickel compound, organic cobalt compound, organic copper compound, organic chromium compound, or a combination thereof.

Abstract: A blanket for transferring a paste image from an engraved plate to a substrate is provided. The blanket includes a foam; a supporting layer on the foam; and a paste transfer layer on the supporting layer. The paste transfer layer is an inter-penetrating polymer network of silicone rubber and fluoroelastomer.

Abstract: A blanket for transferring a paste image from an engraved plate to a substrate is provided. The blanket includes a foam, a PET layer on the foam, and a paste transfer layer on the PET layer. The foam has a Shore A hardness of 20 to 80 and a thickness of 0.5 mm to 1.5 mm, wherein the foam has a higher Shore A hardness corresponding to a greater thickness.

Abstract: A blanket for transferring a paste image from an engraved plate to a substrate is provided. The blanket includes a foam; a supporting layer on the foam; and a paste transfer layer on the supporting layer. The paste transfer layer is an inter-penetrating polymer network of silicone rubber and fluoroelastomer.

Abstract: A curable resin composition, an article, and a method for fabricating the same are provided. The curable resin composition includes a siloxane resin and a catalyst.

Abstract: A curable resin composition, an article, and a method for fabricating the same are provided. The curable resin composition includes an epoxy resin; an anhydride; and a catalyst. In particular, the catalyst includes an imidazole and an organic metal compound, and the organic metal compound includes an organic tin compound, organic zinc compound, organic nickel compound, organic cobalt compound, organic copper compound, organic chromium compound, or a combination thereof.

Abstract: A blanket for transferring a paste image from an engraved plate to a substrate is provided. The blanket includes a foam, a PET layer on the foam, and a paste transfer layer on the PET layer. The foam has a Shore A hardness of 20 to 80 and a thickness of 0.5 mm to 1.5 mm, wherein the foam has a higher Shore A hardness corresponding to a greater thickness.

Abstract: A blanket for transferring a paste image from an engraved plate to a substrate is provided. The blanket includes a foam, a PET layer on the foam, and an paste transfer layer on the PET layer. The blanket has a Tan ? value of 0.05 to 0.13. The foam can be made of polyurethane, polyethylene, nitrile-butadiene rubber, silicone, or a combination thereof. The paste transfer layer can be made of silicone rubber, fluoro rubber, fluorosilicone rubber, a combination thereof, or a multi-layered structure thereof.

Abstract: A method for forming a micro bump includes forming a first nano-particle layer on a substrate and forming a second nano-particle layer on the first nano-particle layer. The first and second nano-particle layers include a plurality of first nano particles and a plurality of second nano particles, respectively. The method further includes irradiating a laser beam onto the second nano-particle layer, where the laser beam penetrates through the second nano-particle layer and is at least partially absorbed by at least some of the first nano particles to generate heat. The first nano particles and the second nano particles have different absorption rates with respect to the laser beam.

Abstract: A method for forming a micro bump includes forming a first nano-particle layer on a substrate and forming a second nano-particle layer on the first nano-particle layer. The first and second nano-particle layers include a plurality of first nano particles and a plurality of second nano particles, respectively. The method further includes irradiating a laser beam onto the second nano-particle layer, where the laser beam penetrates through the second nano-particle layer and is at least partially absorbed by at least some of the first nano particles to generate heat. The first nano particles and the second nano particles have different absorption rates with respect to the laser beam.

Abstract: A thermoelectric alloy material and thermoelectric element are provided, wherein the thermoelectric alloy material includes a Half-Heusler (HH) composition as matrix. The thermoelectric alloy material is represented by following formula (I): (Zra1Hfb1)x(Fec1Cod1)y(Sbe1Snf1)z ??(I) In the formula (I), 0<a1<1, 0<b1<1, 0<c1<1, 0<d1<1, 0<e1<1, 0<f1<1, a1+b1=1, c1+d1=1, e1+f1=1, c1?f1, and 0.25?x, y, z?0.35.

Abstract: A bump with nanolaminated structure is provided. The bump with nanolaminated structure includes a bump, a nanolaminated structure and an organic layer. The nanolaminated structure is located on the bump. The organic layer is located between the bump and the nanolaminated structure. The organic molecular of the organic layer includes two terminal function groups, wherein a first terminal function group is bonded with a first metal atom of the bump and a second terminal function group is bonded with a second metal atom of the nanolaminated structure.

Abstract: A method for manufacturing a substrate with surface substrates by employing photothermal effect is described. Nanoparticles on the surface of the substrate excited by a beam convert light energy to thermal energy. The surface structure on the substrate is formed through the thermal energy generated by the excited nanoparticles. The substrate with plural pores is thus formed.

Abstract: A method for forming a micro bump includes forming a first nano-particle layer on a substrate and forming a second nano-particle layer on the first nano-particle layer. The first and second nano-particle layers include a plurality of first nano particles and a plurality of second nano particles, respectively. The method further includes irradiating a laser beam onto the second nano-particle layer, where the laser beam penetrates through the second nano-particle layer and is at least partially absorbed by at least some of the first nano particles to generate heat. The first nano particles and the second nano particles have different absorption rates with respect to the laser beam.

Abstract: A manufacturing method for manufacturing a substrate with a surface substrate by employing photothermal effect is described. Nanoparticles on the surface of the substrate excited by a beam convert light energy to thermal energy. The surface structure on the substrate is formed through the thermal energy generated by the excited nanoparticles. The substrate with a layer of the predetermined pattern is thus formed.

Abstract: A method for manufacturing core-shell nanostructure is provided. A nanoparticle containing a metal is provided. The nanoparticle is capable of transforming the light energy to the thermal energy. The nanoparticle is distributed onto a first thermosetting material precursor. A second thermosetting material precursor is coated on the first thermosetting material precursor to cover the nanoparticle. The nanoparticle is irradiated by a light source to produce the thermal energy such that the first thermosetting material precursor and the second thermosetting material precursor around the nanoparticle are cured to form a material layer on the nanoparticle. The uncured portion of the first thermosetting material precursor and the uncured portion of the second thermosetting material precursor are removed.

Abstract: A method for manufacturing a substrate with a surface substrate by employing photothermal effect is described. Nanoparticles on the surface of the substrate excited by a beam convert light energy to thermal energy. The surface structure on the substrate is formed through the thermal energy generated by the excited nanoparticles. The substrate with a layer of the predetermined pattern is thus formed.