Abstract: A semiconductor device includes an anisotropic conductive film for connecting the semiconductor device. The anisotropic conductive film includes a first conductive layer that has first conductive particles. The first conductive particles include cores containing silica or a silica composite, and have a 20% K-value ranging from about 7,000 N/mm2 to about 12,000 N/mm2.

Abstract: A chip-on-glass (COG) assembly, in which the electrodes of the semiconductor chips (3) are held in direct connection with the corresponding electrodes on the substrate glass circuit board (1), utilizes a layer (5) of a connecting material for bonding and connecting the semiconductor chip (3) with the substrate board (1). The connecting material can provide a reduced stress concentration at the boundaries between the binder layer (5) and the chip (3) and between the binder layer (5) and the glass board (1), even at higher adhesive strengths, bringing about less deformation, such as warping, of the resulting bonded assembly, even when using a thinner substrate glass board, and provides a superior bonding strength and excellent electroconductive performance. The connecting material is made up of, on the one hand, an adhesive component (6) containing a thermosetting resin and, on the other hand, electroconductive particles (7) and has a characteristic feature that a tensile elongation percentage at 25° C.

Abstract: An adhesive material is used for connecting a protuberant electrode of an electronic component to a terminal electrode of a circuit board for carrying said electronic component through the adhesive material containing at least one curable resin and inorganic particles.

Abstract: A thermosetting adhesive material for connecting connection terminals provided on the opposing sides of a pair of opposing substrates, contains a thermosetting resin and an insulating inorganic filler, wherein the insulating inorganic filler content (a; vol %) and the elastic modulus of the thermosetting adhesive material after curing (E; GPa/30° C.) satisfy the following relational formula (1): 0.042a+0.9<E<0.106a+2.5  (1) and at the same time, the insulating inorganic filler content (a; vol %) and the tensile elongation (d; %) at 25° C. of the thermosetting adhesive material after curing satisfy the following relational formula (2) −0.072a+4<d<−0.263a+13  (2).

Abstract: An adhesive for semiconductor chips contains a first resin component which is polymerizable, a first hardener for inducing a self-polymerization reaction of the first resin component and a second hardener which is addition-polymerized with the first resin component. When the adhesive is applied on a wiring board and a semiconductor chip is applied thereon and heat is applied, the second hardener is addition-polymerized with the backbone of the three-dimensional network formed by the self-polymerization reaction of the first resin component. The first temperature at which the addition polymerization zone becomes a rubbery structure is lower than the second temperature at which the backbone becomes a rubbery structure, so that the elastic modulus loss sharply increases at the first temperature to reduce the stress between the semiconductor chip and the wiring board.

Abstract: An adhesive material is used for connecting a protuberant electrode of an electronic component to a terminal electrode of a circuit board for carrying said electronic component through the adhesive material containing at least one curable resin and inorganic particles. The adhesive material is characterized in that as to the inorganic particles, their specific surface area S (m2/g) satisfies Equation (1) below, their mean particle size D1 (&mgr;m) and maximum particle size D2 (&mgr;m) respectively satisfy Equations (2) and (3) below, 3<S<17  (1) D1≦5  (2) D2≦0.5(h1+h2)  (3) (wherein h1 represents the height of the protuberant electrode in the electronic component, and h2 represents the height of the terminal electrode in the circuit board), and the content of said inorganic particles is 10 to 60 vol %.

Abstract: The present invention is a connection material which enables a flexible circuit board to be connected to a bare IC chip without causing a shoulder touch effect. The connection material contains an insulating adhesive and a flaky or fibrous insulating filler dispersed therein is used for connecting a film-like flexible circuit board and a bare IC chip. The aspect ratio of the flaky or fibrous insulating filler is no less than 20.

Abstract: A connecting material for bonding and connecting elements each having electrodes thereon in a correspondingly confronting relation to each other, while attaining electroconductive connection between the corresponding electrodes, which material has a high heat resistance and can avoid occurrence of faulty electrical conductance even in the case of bonding elements having a large number of electrodes arranged, thus, at a considerably small interval under such a condition that the bonded assembly is exposed to a service environment of high temperature or of high temeperature and high humidity, wherein the connecting material contains a thermosetting resin and an inorganic filler and has, after having been cured, characteristic features of a modulus of elasticity of 1-12 GPa, a glass transition temperature Tg of 120-200° C., a coefficient of linear expansion (&agr;1) of 50 ppm/° C. or less at temperatures below the Tg and a coefficient of linear expansion (&agr;2) of 110 ppm/° C.

Abstract: A method for mounting electronic elements, comprises the step of arranging a thermosetting adhesive between a circuit board, situated on a stage, and an electronic element to be connected with the wiring pattern of the circuit board, and then bonding the electronic element to the circuit board by the application of heat and pressure from the electronic element side. The electronic element is temporarily thermocompression-bonded to the circuit board such that the thermosetting reaction rate of the thermosetting adhesive on the side of the circuit board is lower than the thermosetting reaction rate on the side of the electronic element. The thermosetting adhesive is then set finally in order to bond the electronic element to the circuit board.

Abstract: A connecting material for bonding and connecting elements to be bonded together, each element having electrodes thereon in a correspondingly confronting relationship to each other. The material is highly reliable in the strength of bonding of the elements and in building up electroconductive connection between the corresponding electrodes and can provide mechanical bonding and electrical connection effectively even when bonding an element of a polyimide resin film with a counter element, without the occurrence of a reduction in the reliability of the electrical conductance, even in services under a high temperature and high humidity. The connecting material contains an adhesive component containing a thermosetting resin and has, after having been cured, characteristic features of a modulus of elasticity at 30° C. in the range of 0.9-3 Gpa, a glass transition temperature of at the lowest 100° C. and a tensile elongation percentage of at least 3%.

Abstract: A connecting material that can be used in the mounting of semiconductor devices on a circuit substrate for semiconductor devices, contains the following components A to C: (A) an epoxy resin; (B) a phenol compound having two or more phenolic hydroxyl groups; and (C) a latent curing agent, where it is preferred that if the ratio of the number of phenolic hydroxyl group equivalents of the phenol compound of component B to the number of epoxy equivalents of the epoxy resin in the connecting material is 0.2 to 1.0.

Abstract: A connecting material for anisotropically electroconductive connection for bonding and connecting a semiconductor element having a plurality of electrodes recessed from the outer face of the passivation layer formed on the semiconductor element, on the one hand, with a substrate circuit board having a plurality of electrodes in a correspondingly confronted relation to the electrodes of the semiconductor element, on the other hand, which connecting material can afford to attain simultaneously a reliable mechanical bonding of the element with the circuit board and a secured electroconductive connection between the correspondingly confronted electrodes without suffering from damage of the passivation layer, even if the passivation layer is made of a resin.

Abstract: An anisotropically electroconductive adhesive material is configured of a thermosetting resin and electroconductive particles dispersed in the thermosetting resin, wherein a 10% modulus of compressive elasticity (E) in the electroconductive particles and the modulus of longitudinal elasticity (E′) of the projecting electrodes of the electronic element to be connected by the anisotropically electroconductive adhesive material satisfy the below relational Formula (1) 0.

Abstract: The present invention is a connection material which enables a flexible circuit board to be connected to a bare IC chip without causing a shoulder touch effect. The connection material contains an insulating adhesive and a flaky or fibrous insulating filler dispersed therein is used for connecting a film-like flexible circuit board and a bare IC chip. The aspect ratio of the flaky or fibrous insulating filler is no less than 20.

Abstract: An adhesive for semiconductor chips contains a first resin component which is polymerizable, a first hardener for inducing a self-polymerization reaction of the first resin component and a second hardener which is addition-polymerized with the first resin component. When the adhesive is applied on a wiring board and a semiconductor chip is applied thereon and heat is applied, the second hardener is addition-polymerized with the backbone of the three-dimensional network formed by the self-polymerization reaction of the first resin component. The first temperature at which the addition polymerization zone becomes a rubbery structure is lower than the second temperature at which the backbone becomes a rubbery structure, so that the elastic modulus loss sharply increases at the first temperature to reduce the stress between the semiconductor chip and the wiring board.

Abstract: Substrate warpage is eliminated without adversely affecting connection reliability when an IC chip or other packaging component is mounted on a substrate by thermocompression bonding with an interposed thermosetting adhesive. In a packaging method for the thermocompression bonding of a substrate and an IC chip or other packaging component between a stage and a head by means of an interposed thermosetting adhesive, the temperature of the stage during thermocompression bonding is set above the temperature corresponding to the inflection point of the elastic modulus in the relationship between the elastic modulus and the temperature of the cured adhesive.

Abstract: A connecting material that can be used in the mounting of semiconductor devices on a circuit substrate for semiconductor devices, contains the following components A to C:

Abstract: An anisotropically electroconductive adhesive material is configured of a thermosetting resin and electroconductive particles dispersed in the thermosetting resin, wherein a 10% modulus of compressive elasticity (E) in the electroconductive particles and the modulus of longitudinal elasticity (E′) of the projecting electrodes of the electronic element to be connected by the anisotropically electroconductive adhesive material satisfy the below relational Formula (1).

Abstract: A thermosetting adhesive material for connecting connection terminals provided on the opposing sides of a pair of opposing substrates, contains a thermosetting resin and an insulating inorganic filler,

Abstract: A multilayer anisotropic electroconductive adhesive, comprises an anisotropic electroconductive adhesive layer and laminated to at least one side thereof an insulating adhesive layer. The anisotropic electroconductive adhesive layer comprises a film-forming resin and electroconductive particles and has a melt viscosity at 150.degree. C. of 100 poise or higher, and the insulating adhesive layer comprises a latent curing agent and a resin having a functional group and has a melt viscosity at 150.degree. C. of less than 100 poise.