Abstract: An adhesive agent having excellent bonding properties with oxide films and excellent heat-dissipation properties and a connection structure using the same. The adhesive agent contains an epoxy compound, a cationic catalyst, and an acrylic resin containing acrylic acid and acrylic acid ester having a hydroxyl group. Acrylic acid in the acrylic resin reacts with the epoxy compound to generate connections between an island of acrylic resin and a sea of epoxy compound and roughen the surface of an oxide film to improve an anchor effect with the sea of epoxy compound; solder particles contained in the adhesive agent are melted to form metal bonding with an electrode, thereby enabling improvement in adhesive strength between the adhesive agent and the electrode and further improving heat dissipation from a surface of the metal bonding.

Abstract: This adhesive contains an epoxy compound, a cationic catalyst, and an acrylic resin that includes acrylic acid and an acrylic acid ester having a hydroxyl group. The acrylic acid in the acrylic resin reacts with the epoxy compound, creating a link between the acrylic resin island part and the epoxy compound sea part, and strengthening the anchoring effect with respect to the epoxy compound sea part by roughening the surface of an oxide film. Furthermore, the hydroxyl-group-containing acrylic acid ester in the acrylic resin becomes electrostatically adhesive to wiring due to the polarity of the hydroxyl group. Excellent adhesive strength can be obtained by adhering, in this way, the entire cured product composed of the acrylic resin island part and the epoxy compound sea part to the oxide film.

Abstract: An anisotropic conductive adhesive in which high thermal dissipation is provided. Conductive particles and solder particles are dispersed in a binder. In a thermally compressed LED device manufactured using this anisotropic conductive adhesive, terminals of the LED device are electrically connected to terminals of a substrate via particles and the terminals of the LED device and the terminals of the substrate are solder bonded.

Abstract: Provided is an anisotropic conductive adhesive in which excellent optical characteristics and heat dissipation characteristics are obtainable. The anisotropic conductive adhesive contains conductive particles each comprising a metal layer having Ag as a primary constituent formed on an outermost surface of a resin particle, solder particles having a smaller average particle diameter than the conductive particles, reflective insulating particles having a smaller average particle diameter than the solder particles and a binder into which the conductive particles solder particles and reflective insulating particles are dispersed. The conductive particles and the reflective insulating particles efficiently reflect light, thereby improving light-extraction efficiency of an LED mounting body. Additionally, inter-terminal solder bonding of the solder particles during compression bonding increases contact area between opposing terminals, thereby enabling achievement of high heat dissipation characteristics.

Abstract: Provided is an anisotropic conductive adhesive in which excellent optical characteristics and heat dissipation characteristics are obtainable. The anisotropic conductive adhesive contains conductive particles each comprising a metal layer having Ag as a primary constituent formed on an outermost surface of a resin particle, solder particles having a smaller average particle diameter than the conductive particles, reflective insulating particles having a smaller average particle diameter than the solder particles and a binder into which the conductive particles solder particles and reflective insulating particles are dispersed. The conductive particles and the reflective insulating particles efficiently reflect light, thereby improving light-extraction efficiency of an LED mounting body. Additionally, inter-terminal solder bonding of the solder particles during compression bonding increases contact area between opposing terminals, thereby enabling achievement of high heat dissipation characteristics.

Abstract: An adhesive agent having excellent bonding properties with oxide films and excellent heat-dissipation properties and a connection structure using the same. The adhesive agent contains an epoxy compound, a cationic catalyst, and an acrylic resin containing acrylic acid and acrylic acid ester having a hydroxyl group. Acrylic acid in the acrylic resin reacts with the epoxy compound to generate connections between an island of acrylic resin and a sea of epoxy compound and roughen the surface of an oxide film to improve an anchor effect with the sea of epoxy compound; solder particles contained in the adhesive agent are melted to form metal bonding with an electrode, thereby enabling improvement in adhesive strength between the adhesive agent and the electrode and further improving heat dissipation from a surface of the metal bonding.

Abstract: Provided is a light emitting device high in the intensity of emitted light. A blue LED chip having a peak of emitted light in a wavelength range of at least 360 nm and at most 500 nm is adhered to an electrode substrate by an anisotropic conductive adhesive. A light reflecting layer made of a silver alloy on a surface of each conductive particle contained in the anisotropic conductive adhesive, and has high reflectance with respect to blue light. The light reflecting layer is formed by sputtering of a sputtering target that contains Ag, Bi, and Nd with the content ratio of Bi set to at least 0.1 weight % (wt %) and at most 3.0 wt % and the content ratio of Nd set to at least 0.1 weight % and at most 2.0 wt % with respect to the total weight of Ag, Bi, and Nd of 100 wt %. The conductive particle has high anti-migration properties.

Abstract: In order to provide a light emitting device having high connection reliability, the light-emitting device includes a board provided with a wiring pattern, an anisotropic conductive paste arranged on an board electrode of the wiring pattern, and a light-emitting element embedded in the anisotropic conductive paste, and at least one of the board electrode and the element electrode is plated with an AuSn alloy layer. The anisotropic conductive paste contains an epoxy compound, an acid anhydride, white inorganic particles, and conductive particles obtained by coating resin particles with an Au coating layer. It is possible to maintain electrical connection between the board electrode and the element electrode by the Au coating layers of the conductive particles even when a crack is generated in a eutectic bonding portion. Therefore, it is possible to obtain high connection reliability.

Abstract: This adhesive contains an epoxy compound, a cationic catalyst, and an acrylic resin that includes acrylic acid and an acrylic acid ester having a hydroxyl group. The acrylic acid in the acrylic resin reacts with the epoxy compound, creating a link between the acrylic resin island part and the epoxy compound sea part, and strengthening the anchoring effect with respect to the epoxy compound sea part by roughening the surface of an oxide film. Furthermore, the hydroxyl-group-containing acrylic acid ester in the acrylic resin becomes electrostatically adhesive to wiring due to the polarity of the hydroxyl group. Excellent adhesive strength can be obtained by adhering, in this way, the entire cured product composed of the acrylic resin island part and the epoxy compound sea part to the oxide film.

Abstract: A light-reflective anisotropic conductive adhesive is used for anisotropic conductive connection of a light-emitting element to a wiring board. The adhesive includes a thermosetting resin, conductive particles, and light-reflective acicular insulating particles. The conductive particles comprise a core particle coated with a metal particle or a metal material, and a light reflective layer formed on a surface of the core particle. The light reflective layer comprises inorganic particles selected from any one of titanium oxide particles, zinc oxide particles or aluminum oxide particles until the entire conductive particle appears a color in a range from white to gray.

Abstract: Provided is a light emitting device high in the intensity of emitted light. A blue LED chip having a peak of emitted light in a wavelength range of at least 360 nm and at most 500 nm is adhered to an electrode substrate by an anisotropic conductive adhesive. A light reflecting layer made of a silver alloy on a surface of each conductive particle contained in the anisotropic conductive adhesive, and has high reflectance with respect to blue light. The light reflecting layer is formed by sputtering of a sputtering target that contains Ag, Bi, and Nd with the content ratio of Bi set to at least 0.1 weight % (wt %) and at most 3.0 wt % and the content ratio of Nd set to at least 0.1 weight % and at most 2.0 wt % with respect to the total weight of Ag, Bi, and Nd of 100 wt %. The conductive particle has high anti-migration properties.

Abstract: An anisotropic conductive adhesive in which high thermal dissipation is provided. Conductive particles and solder particles are dispersed in a binder. In a thermally compressed LED device manufactured using this anisotropic conductive adhesive, terminals of the LED device are electrically connected to terminals of a substrate via particles and the terminals of the LED device and the terminals of the substrate are solder bonded.

Abstract: An anisotropic conductive adhesive includes: a conductive particle including a resin particle and a conductive metal layer that is formed on a surface of the resin particle; a thermally conductive particle that is a metal particle or an insulation coated particle, wherein the metal particle has an average particle size that is smaller than an average particle size of the conductive particle, and the insulation coated particle has an average particle size that is smaller than the average particle size of the conductive particle and includes a metal particle and an insulating layer that is formed on a surface of the metal particle; and an adhesive component in which the conductive particle and the thermally conductive particle are dispersed.

Abstract: A light-reflective anisotropic conductive adhesive is used for anisotropic conductive connection of a light-emitting element to a wiring board. The adhesive includes a thermosetting resin, conductive particles, and light-reflective acicular insulating particles. The conductive particles comprise a core particle coated with a metal particle or a metal material, and a light reflective layer formed on a surface of the core particle. The light reflective layer comprises inorganic particles selected from any one of titanium oxide particles, zinc oxide particles or aluminum oxide particles until the entire conductive particle appears a color in a range from white to gray.

Abstract: an anisotropic conductive adhesive which uses conductive particles where a silver-based metal is used as a conductive layer, having high light reflectance and excellent migration resistance is provided. The anisotropic conductive adhesive includes light reflective conductive particles in an insulating adhesive resin. The light reflective conductive particle includes a light reflective metal layer made of a metal alloy including silver, gold and hafnium formed on the surface of a resin particle as a core by sputtering method. The light reflective metal layer is preferably formed having a composition ratio of a silver of at least 50% by weight to at most 80% by weight: a gold of at least 10% by weight to at most 45%: a hafnium of at least 10% by weight to at most 40% by weight, and a total ratio does not exceed 100% by weight.

Abstract: A light-reflective anisotropic conductive adhesive and light-emitting device capable of maintaining luminous efficiency of a light-emitting element and preventing the occurrence of a crack to obtain conduction reliability are provided. The light-reflective anisotropic conductive adhesive contains a thermosetting resin composite, conductive particles, and a light-reflective acicular insulating particles. These light-reflective acicular insulating particles are inorganic particles of at least one type selected from the group including titanium oxide, zinc oxide, and titanate.

Abstract: A light-reflective anisotropic conductive adhesive used for anisotropic conductive connection of a light-emitting element to a wiring board includes a thermosetting resin composition containing a silicone resin and a curing agent, conductive particles and light-reflective insulating particles. The light-reflective insulating particle is at least one kind of inorganic particles selected from the group consisting of titanium oxide, boron nitride, zinc oxide, silicon oxide, and aluminum oxide. The silicone resin is a glycidyloxyalkyl-alicyclic alkyl-modified organopolysiloxane.

Abstract: A buffer film for multi-chip packaging which does not cause out of alignment during multi-chip packaging and ensures favorable connection reliability has a structure in which a heat-resistant resin layer having a linear expansion coefficient of 80 ppm/° C. or less and a flexible resin layer made of a resin material having a Shore A hardness according to JIS K6253 of 10 to 80 are laminated. A multi-chip module can be produced by aligning a plurality of chip devices on a substrate through an adhesive to perform temporary adhesion, disposing the buffer film for multi-chip packaging between the chip devices and a bonding head so that the heat-resistant resin layer is on a chip device side, and connecting the plurality of chip devices with the substrate by applying heat and pressure to the chip devices toward the substrate with the bonding head.

Abstract: An anisotropic conductive adhesive which uses conductive particles where a silver-based metal is used as a conductive layer, having high light reflectance and excellent migration resistance is provided. The anisotropic conductive adhesive includes light reflective conductive particles in an insulating adhesive resin. The light reflective conductive particle includes a light reflective metal layer made of a metal having at least 60% of reflectance at a peak wavelength of 460 nm formed on the surface of a resin particle as a core, and a coating layer made of a silver alloy formed on the surface of the light reflective metal layer. The light reflective metal layer is preferably formed by a plating method.

Abstract: A buffer film for multi-chip packaging which does not cause out of alignment during multi-chip packaging and ensures favorable connection reliability has a structure in which a heat-resistant resin layer having a linear expansion coefficient of 80 ppm/° C. or less and a flexible resin layer made of a resin material having a Shore A hardness according to JIS K6253 of 10 to 80 are laminated. A multi-chip module can be produced by aligning a plurality of chip devices on a substrate through an adhesive to perform temporary adhesion, disposing the buffer film for multi-chip packaging between the chip devices and a bonding head so that the heat-resistant resin layer is on a chip device side, and connecting the plurality of chip devices with the substrate by applying heat and pressure to the chip devices toward the substrate with the bonding head.