Abstract: A new silicone condensation reaction, the condensation between an alkoxy silane or siloxane and an organo-hydrosilane or siloxane and catalysts therefore is described and claimed.

Abstract: The present invention relates to curable alkenyl based silicone release coating compositions having improved adhesion to paper and polymeric substrates. Furthermore the present invention relates to the process for making a silicone release coating with improved adhesion to paper and polymeric substrates.

Abstract: A sensor package and method are described. The sensor package includes an enclosure, a diaphragm coupled to the enclosure. The diaphragm is configured to receive vibrations from an ambient environment. Further, the sensor package includes a pressure sensing element disposed inside the enclosure, and a pressure transfer medium disposed inside the enclosure and proximate the pressure sensing element, where the pressure transfer medium includes a fluid, and a plurality of filler particles suspended in the fluid. The filler particles serve to reduce a coefficient of thermal expansion of the pressure transfer medium.

Abstract: A composition for use as underfill material is provided. The underfill material includes a first curable transparent resin composition and a second curable fluxing resin composition. The first curable resin composition includes at least one aromatic epoxy resin in combination with a solvent, a functionalized colloidal silica dispersion, and at least one other component selected from the group consisting of cycloaliphatic epoxy monomers, aliphatic epoxy monomers, hydroxy aromatic compounds and combinations and mixtures thereof, thereby forming a solvent-modified resin. The second curable fluxing composition includes at least one epoxy resin. The combination of the two resin compositions is useful in producing underfill materials and is suitable for use as an encapsulant for electronic chips.

Abstract: Thermal interface compositions contain nanoparticles blended with a polymer matrix. Such compositions increase the bulk thermal conductivity of the polymer composites as well as decrease thermal interfacial resistances that exist between thermal interface materials and the corresponding mating surfaces. Formulations containing nanoparticles also show less phase separation of micron-sized particles than formulations without nanoparticles.

Abstract: An encapsulant composition is provided. The composition includes an epoxy composition including at least a silicone epoxy of the general formula: MaM?bDcD?dTeT?fQg wherein a, b, c, d, e, f, and g are independently integers of zero or above, and wherein the sum of b, d, and f is one or greater; M is R13SiO1/2; M? is (Z)R22SiO1/2; D is R32SiO2/2; D? is (Z)R4SiO2/2; T is R5SiO3/2; and T? is (Z)SiO3/2; Q is SiO4/2 and R1, R2, R3, R4, R5 are independently selected from the group consisting of H, C1-22 alkyl, C1-22 alkoxy, C2-22 alkenyl, C6-14 aryl, C6-22 alkyl substituted aryl, C6-22 arylalkyl, aminoalkyls, and mixtures thereof; and Z, independently at each occurrence, is an organic radical containing an epoxy group, a curing agent, and a filler. The composition is substantially free of Pt.

Abstract: A finely divided refractory solid and an associated method are provided. The solid may have a surface area that is greater than about 5 square meters per gram. The solid may have a density of active surface termination sites per square nanometer of surface area sufficiently low that a curable composition comprising a curable resin that comprises less than about 99 percent by weight of the solid has a stability ratio of less than about 3 after a period of about two weeks. Also, a curable composition, a cured layer, and an electronic device that includes the cured layer are provided.

Abstract: Epoxy resin compositions are disclosed which comprise (A) at least one silicone epoxy resin, (B) at least one hydroxyl-containing compound, (C) at least one anhydride curing agent, (D) at least one ancillary curing catalyst, and optionally at least one of thermal stabilizers, UV stabilizers, cure modifiers, coupling agents, or refractive index modifiers. Also disclosed are packaged solid state devices comprising a package, a chip (4), and an encapsulant (11) comprising an epoxy resin composition of the invention. A method of encapsulating a solid state device is also provided.

Abstract: Siloxane cross-linked polyolefins provide for a composition that is more or less impermeable to gaseous sulfur compounds such as hydrogen sulfide providing for a protective coating for various articles of manufacture especially electronic components and a method of protecting various articles of manufacture from the effects of such gaseous sulfur compounds.

Abstract: A curable epoxy formulation comprises an epoxy monomer, an epoxy oligomer, or a combination thereof; an organofunctionalized colloidal silica; a cure catalyst; and optional reagents. Further embodiments of the present invention include a method for making the curable epoxy formulation and a semiconductor package comprising the curable epoxy formulation. Embodiments of cured formulations can have low coefficients of thermal expansion and/or high glass transition temperatures.

Abstract: A composition comprises a first curable resin composition that includes at least one aromatic epoxy resin in combination with a solvent, a functionalized colloidal silica dispersion, and at least one other component selected from the group consisting of cycloaliphatic epoxy monomers, aliphatic epoxy monomers, hydroxy aromatic compounds, combinations thereof, and mixtures thereof. The composition can include a separate second curable fluxing composition that comprises at least one epoxy resin. The first curable resin or the combination of the two resin compositions is useful in producing underfill materials and is suitable for use as an encapsulant for electronic chips.

Abstract: Thermal interface compositions contain nanoparticles blended with a polymer matrix. Such compositions increase the bulk thermal conductivity of the polymer composites as well as decrease thermal interfacial resistances that exist between thermal interface materials and the corresponding mating surfaces. Formulations containing nanoparticles also show less phase separation of micron-sized particles than formulations without nanoparticles.

Abstract: Epoxy resin compositions are disclosed which comprise (A) at least one silicone epoxy resin, (B) at least one hydroxyl-containing compound, (C) at least one anhydride curing agent, (D) at least one ancillary curing catalyst, and optionally at least one of thermal stabilizers, UV stabilizers, cure modifiers, coupling agents, or refractive index modifiers. Also disclosed are packaged solid state devices comprising a package, a chip (4), and an encapsulant (11) comprising an epoxy resin composition of the invention. A method of encapsulating a solid state device is also provided.

Abstract: A composition for use as underfill material is provided. The underfill material includes a first curable transparent resin composition and a second curable fluxing resin composition. The first curable resin composition includes at least one aromatic epoxy resin in combination with a solvent, a functionalized colloidal silica dispersion, and at least one other component selected from the group consisting of cycloaliphatic epoxy monomers, aliphatic epoxy monomers, hydroxy aromatic compounds and combinations and mixtures thereof, thereby forming a solvent-modified resin. The second curable fluxing composition includes at least one epoxy resin. The combination of the two resin compositions is useful in producing underfill materials and is suitable for use as an encapsulant for electronic chips.

Abstract: An underfill composition with enhanced adhesion and improved resistance to cracking comprising an epoxy resin in combination with a difunctional siloxane anhydride epoxy hardener and optional reagents. In some embodiments, the epoxy resin includes a functionalized colloidal silica filler having a particle size ranging from about 1 nm to about 500 nm. The difunctional siloxane anhydride epoxy hardener can optionally be combined with liquid anhydride epoxy hardeners. Cure catalysts, hydroxyl-containing monomers, adhesion promoters, flame retardants and defoaming agents may also be added to the composition. Further embodiments of the present disclosure include packaged solid state devices comprising the underfill compositions.

Abstract: Siloxane cross-linked polyolefins provide for a composition that is more or less impermeable to gaseous sulfur compounds such as hydrogen sulfide providing for a protective coating for various articles of manufacture especially electronic components and a method of protecting various articles of manufacture from the effects of such gaseous sulfur compounds.

Abstract: A solvent-modified resin composition for use as underfill material is provided. The composition having at least one epoxy resin, at least one solvent and a filler of functionalized colloidal silica. The solvent-modified resin composition is useful in making transparent B-stage resin films. Embodiments of the disclosure include use as a wafer level underfill, and an encapsulant for electronic chips.

Abstract: A no-flow underfill composition comprising an epoxy resin in combination with epoxy hardener and optional reagents and a filler of a functionalized colloidal silica having a particle size ranging from about 1 nm to about 250 nm. The colloidal silica is functionalized with at least one organoalkoxysilane functionalization agent and subsequently functionalized with at least one capping agent. The epoxy hardener includes anhydride curing agents. The optional reagents include cure catalyst and hydroxyl-containing monomer. The adhesion promoters, flame retardants and defoaming agents may also be added to the composition. Further embodiments of the present disclosure include packaged solid state devices comprising the underfill compositions.

Abstract: A curable epoxy formulation is provided in the present invention. The formulation comprises an epoxy monomer, an organofunctionalized colloidal silica having a particle size in a range between about 2 nanometers and about 20 nanometers, and optional reagents wherein the organofunctionalized colloidal silica substantially increases the glass transition temperature of the epoxy formulation. Further embodiments of the present invention include a semiconductor package comprising the aforementioned curable epoxy formulation.

Abstract: A new silicone condensation reaction, the condensation between an alkoxy silane or siloxane or a dihydric phenol and an organo-hydrosilane or siloxane and catalysts therefore is described and claimed.