Abstract: A liquid epoxy resin composition for semiconductor encapsulation comprising: (A) at least one epoxy resin, (B) at least one curing accelerator and (C) at least one acid anhydride terminated polyamic acid, and an assembly in which a cured material of the liquid epoxy resin is positioned between a printed circuit substrate and semiconductor die. The liquid epoxy resin composition provides a cured material that has an excellent adhesiveness to a semiconductor chip surface and has an excellent moisture resistance.

Abstract: A liquid epoxy resin composition for semiconductor encapsulation comprising: (A) an epoxy resin, (B) an imidazole compound, and (C) a maleimide compound, a semiconductor device encapsulated by the liquid epoxy resin composition, and an assembly in which a cured material of the liquid epoxy resin is positioned between a printed circuit substrate and a semiconductor die. The liquid epoxy resin composition provides a cured material that has an excellent adhesiveness to a semiconductor chip surface and has an excellent moisture resistance.

Abstract: Disclosed is a lithium ion secondary battery that has a simple structure, is easily produced, and wherein short circuits do not arise. The lithium ion secondary battery comprises an active material being contained in a matrix comprising a laminated body that includes a positive current collector and a negative current collector which are laminated on each other via a solid electrolyte layer, the solid electrolyte layer includes an active material in a matrix made of solid electrolyte, and a ratio of the volume of the solid electrolyte and the volume of the active material being 90:10-65:35. Also, the active material may also be contained in a matrix of a conductive substance of the positive current collector and/or the negative current collector.

Abstract: It is difficult to display the polarity of terminal electrodes of lithium ion batteries. With conventional lithium ion secondary batteries, since different materials are employed for the active substances that make up a positive electrode and a negative electrode, problems arise if the polarities of the electrodes are mistaken when the battery is installed. A battery has been developed using an active substance material functioning as a secondary battery even when the same material is used for the active substances that make up the positive electrode and the negative electrode, and a non-polar secondary battery has been produced. With no distinction between the terminal electrodes, attention does not need to be paid to the direction of installation, thereby simplifying the installation step. Furthermore, since there is no need to manufacture a positive electrode layer and a negative electrode layer separately, the step for manufacturing the battery is also simplified.

Abstract: A method of producing a crystalline silicon solar cell, comprising: printing a conductive paste on a crystalline silicon substrate, and firing the conductive paste to form a light incident side electrode, wherein the conductive paste comprises conductive particles, glass frits, an organic binder and a solvent, the conductive particles comprise zinc particles and copper particles, and a weight ratio of the zinc particles and the copper particles is 2:1 to 2:3.

Abstract: A method for producing a solar cell, including printing a conductive paste on a crystalline silicon substrate, and firing the conductive paste to form a light incident side electrode, wherein the conductive paste comprises conductive particles, glass frits, an organic binder and a solvent, wherein the conductive particles comprise (A) silver, and (B) one or more metals selected from the group consisting of copper, nickel, aluminum, zinc and tin, and the weight proportion (A):(B) is 5:95 to 90:10.

Abstract: Underfill materials include inorganic fill materials (e.g., functionalized CNT's, organo clay, ZnO) that are functionalized reactive with other organic constituents (e.g., organics with epoxy groups, amine groups, or PMDA). The underfill materials also beneficially include polyhedral oligomeric silsesquioxane and/or dendritic siloxane groups that are functionalized with a reactive group (e.g., glycidyl) that reacts with other components of an epoxy system of the underfill.

Abstract: Disclosed is a thermosetting conductive paste which is advantageous in that an external electrode for multilayer ceramic electronic part formed using the paste exhibits excellent bonding properties with an internal electrode and is suitable for mounting on a substrate or plating, achieving excellent electric properties (electrostatic capacity, tan ?. A thermosetting conductive paste comprising: (A) metal powder having a melting point of 700° C. or higher; (B) metal powder having a melting point of higher than 300 to lower than 700° C.; and (C) a thermosetting resin.

Abstract: A solar cell containing an electrode, wherein the electrode is formed by firing a conductive paste, wherein the conductive paste includes an organic binder, a solvent, conductive particles, glass frits and a compound containing Al, Ga, In or Tl. A method for producing a solar cell by forming an electrode by firing a conductive paste, wherein the conductive paste includes an organic binder, a solvent, conductive particles, glass frits and a compound containing Al, Ga, In or Tl.

Abstract: Secondary batteries for automobiles require good input/output characteristics and low internal resistance. Conventionally, the surface of an active material is coated with metal particles to reduce the internal resistance of a battery, but without achieving remarkable improvement in the conductivity of the active material or decreasing the internal resistance of the battery since an oxide film is formed on the metal particle surfaces. The present electrode material is produced by mixing and dispersing an active material and a metal source compound, then depositing metal particles on the surface of the active material by thermal decomposition, vapor phase reduction, liquid phase reduction or a chemical reaction combining any of these. Since an oxide film is not formed on the metal particles, an electrode material having high conductivity is obtained. The electrode material decreases the internal resistance of a battery and improves the input/output characteristics of a battery.

Abstract: A conventional, multilayer, all-solid-state, lithium ion secondary battery where an electrode layer and an electrolyte layer are stacked has a problem that it has a high interface resistance between the electrode layer and the electrolyte layer and has a difficulty in increasing the capacity of the battery. A battery has been manufactured by applying pastes of a mixture of an active material and a solid electrolyte to form electrode layers and baking a laminate of electrode layers and electrolyte layers at a time. As a result, a matrix structure including the active material and the solid electrolyte has been formed in the electrode layers, so that a battery with a large capacity and a reduced interface resistance between the electrode layer and the electrolyte layer has been successfully achieved.

Abstract: By an electronic component mounting method for electrically connecting bumps to board electrodes, in a contact process for placing a thermosetting resin in a liquid glob state on the board surface and bringing the lower surface of the electronic component into contact with the thermosetting resin, the bumps are pressurized against the electrodes in positional alignment in a liquid glob distribution state where one portion of the liquid glob is arranged inside an electronic component mounting region and a remaining portion greater in liquid measure than the one portion is arranged outside the electronic component mounting region. The thermosetting resin enters into a gap between the electronic component and the board by capillarity in a thermocompression bonding process. This prevents voids occurring in the sealing resin, reinforces bonded portions of bumps and electrodes with thermally cured thermosetting resin, thereby preventing bonded portion breakage due to thermal stress generated during cooling.

Abstract: The objective of the present invention is to provide a shield method and shield material enabling to hold a flexibility degree with an enclosure shape and to make electronic component enclosures small and thin types. The shield method for electronic component enclosures in the present invention comprises a process in which a conductive layer is formed at a basic sheet and a shield sheet forming a non-hardening adhesive layer at the counter face to the basic layer is punched out to fit in individual electronic component enclosures for forming the shield materials, a process in which the shield material is attached to said electronic component enclosure, and a process in which a conductive adhesive is formed between a ground electrode set at said electronic component enclosure and the conductive layer to connect electrically.

Abstract: A method for producing a light emitting diode chip encapsulation product, the method comprising covering a light emitting diode chip connected onto a substrate with a thermosetting film, and thermally curing the thermosetting film.

Abstract: A multilayer whole solid-type lithium ion rechargeable battery has hitherto been produced by stacking green sheets of a positive electrode layer, a solid electrolyte layer, and a negative electrode layer, which are formed of respective materials different from each other in coefficient of thermal expansion, and firing the layers at a time. This technique poses problems of delamination and nonlamination attributable to a difference in shrinkage. The problems can be solved by forming green sheets with the addition of a sintering aid to each starting material powder for the positive electrode layer, the solid electrolyte layer, and the negative electrode layer and performing control, by setting the additive rate of the sintering aid and the firing temperature, so that the shrinkages of the respective green sheets are substantially equal to each other. Consequently, unfavorable phenomena such as delamination can be prevented.

Abstract: The invention relates to a liquid resin composition for underfill comprising (A) an epoxy resin, (B) an amine-based curing agent, and (C) an inorganic filler, a viscosity at a temperature of 25° C. being 1 to 150 Pa·s, and a time required for the viscosity to become 1 Pa·s at a temperature of 100° C. being 40 to 180 minutes.

Abstract: Conventional ion rechargeable batteries having an electrode layer on an electrolyte layer suffer from an impurity layer formed at the interface, degrading performance. Conventional batteries with no such impurity layer have a problem of weak interface bonding. In the present invention, in a baking process step after an electrode layer is laminated on an electrolyte layer, materials for an electrode layer and an electrolyte layer are selected such that an intermediate layer formed of a reaction product contributing to charging and discharging reactions is formed at the interface of the electrode layer and the electrolyte layer. In addition, a paste that an active material is mixed with a conductive material at a predetermined mixing ratio is used to form a positive electrode layer and a negative electrode layer. Reductions in electrode resistance and interface resistance and improvement of charging and discharging cycle characteristics are made possible.

Abstract: The present invention is intended to solve the problem of a conventional thermosetting conductive paste with respect to bonding-property between an internal electrode(s) and an external electrode(s) so as to provide a multilayer ceramic electronic part suitable for its mounting on a substrate and for its plating-treatment. The present invention relates to a multilayer ceramic electronic part, characterized in that it has an external electrode(s) formed from a thermosetting conductive paste comprising conductive particles having a high melting point, metal powder having a melting point of 300° C. or less and a resin(s).

Abstract: In multilayer wholly solid lithium ion secondary batteries, a laminate having a collector layer of material with high conductivity superimposed on an active material layer has been disposed so as to attain a lowering of battery impedance. Consequently, in the fabrication of each of positive electrode layer and negative electrode layer, stacking of three layers consisting of an active material layer, a collector layer and an active material layer has been needed, thereby posing the problem of complex processing and high production cost. In the invention, a positive electrode layer and a negative electrode layer are fabricated from paste consisting of active material mixed with conductive substance in a given mixing ratio, and no collector layer is disposed. This realizes process simplification and manufacturing cost reduction without deterioration of battery performance and has also been effective in enhancing of battery performance, such as improvement to cycle characteristics.

Abstract: Conductive adhesives, which do not have the problem of migration in conductive metals upon application of a voltage and which exhibit low resistance values, are provided. One embodiment of the present invention relates to a conductive adhesive comprising a conductive filler and a resin, characterized in that the conductive filler comprises an alloy powder of silver and tin and further contains an additive comprising at least one member selected from among a chelator, an antioxidant, and a metal surfactant. Additives that can be used are chelators such as hydroxyquinolines, salicylidene aminothiophenols or phenanthrolines, antioxidants such as hydroquinones or benzotriazoles, and metal surfactants such as organic acids, acid anhydrides or organic acid salts.