The embodiment of the present application relates to the field of Li-ion battery and, in particular, to a secondary battery. The secondary battery includes a cell, a safety component fixed on the cell and thermal conductive adhesive provided between the cell and the safety component, the thermal conductive adhesive contains at least one of hot melt adhesive, silica gel binder or epoxy resin binder, and thermal conductive filling material. The thermal conductive adhesive in the secondary battery performs good thermal conductivity and adhering property, which can stably adhere the safety component with the cell, meanwhile transferring, via the thermal conductive adhesive, heat of the cell to the safety component rapidly, so that the safety component cuts off the circuit to protect the cell during overcharge, thereby avoid situations that the thermal conductive adhesive is separated from the cell due to cell inflation and deformation.

A heat-dissipating structure is formed by bonding a first member and a second member, each being any of a metal, ceramic, and semiconductor, via a die bonding member; or a semiconductor module formed by bonding a semiconductor chip, a metal wire, a ceramic insulating substrate, and a heat-dissipating base substrate including metal, with a die bonding member interposed between each. At least one of the die bonding members includes a lead-free low-melting-point glass composition and metal particles. The lead-free low-melting-point glass composition accounts for 78 mol % or more in terms of the total of the oxides V2O5, TeO2, and Ag2O serving as main ingredients. The content of each of TeO2 and Ag2O is 1 to 2 times the content of V2O5, and at least one of BaO, WO3, and P2O5 is included as accessory ingredients, and at least one of Y2O3, La2O3, and Al2O3 is included as additional ingredients.

The invention relates generally to use of a silicon oxynitride film which exhibits desirable physical and chemical properties; superiority in adhesion to metals including noble metals and other metals, transparent conductive oxides, and semiconductor materials compared to silicon dioxide and silicon nitride; is wet-etchable, dry-etchable, or both; and operates as a high-performance overcoat barrier dielectric. The silicon oxynitride film meets performance requirements via a process that does not require an adhesion layer for deposition, and does not contaminate, obscure, or damage the device through incorporation or processing of additional adhesion layers.

The invention relates generally to use of a silicon oxynitride film which exhibits desirable physical and chemical properties; superiority in adhesion to metals including noble metals and other metals, transparent conductive oxides, and semiconductor materials compared to silicon dioxide and silicon nitride; is wet-etchable, dry-etchable, or both; and operates as a high-performance overcoat barrier dielectric. The silicon oxynitride film meets performance requirements via a process that does not require an adhesion layer for deposition, and does not contaminate, obscure, or damage the device through incorporation or processing of additional adhesion layers.

The present invention relates to a nano-diamond dispersion solution and a method of preparing the same. The method of preparing a nano-diamond dispersion solution comprises the following steps: providing a nano-diamond aggregation; mixing the nano-diamond aggregation with a metal hydroxide solution and stirring the mixture such that the nano-diamond aggregation is separated, to obtain a mixture solution; stabilizing the mixture solution such that the mixture solution is separated into a supernatant and precipitates; and extracting the supernatant and precipitates.

The present invention relates to a nano-diamond dispersion solution and a method of preparing the same. The method of preparing a nano-diamond dispersion solution comprises the following steps: providing a nano-diamond aggregation; mixing the nano-diamond aggregation with a metal hydroxide solution and stirring the mixture such that the nano-diamond aggregation is separated, to obtain a mixture solution; stabilizing the mixture solution such that the mixture solution is separated into a supernatant and precipitates; and extracting the supernatant and precipitates.

A bonding and sealing material includes, as the essential ingredients, a solder powder, silver nanoparticles coated with a coating material and a solvent, and additionally includes at least one ingredient selected from the group consisting of selenium metal, oxide film inhibitors and oxide film removers. This bonding and sealing material can easily form under mild conditions a metallic adhesive layer having good hermetic sealability and UV resistance of the sort desired when sealing a short-wavelength light-emitting device such as a UV-LED, and can be stably used over a long period of time.

A bonding and sealing material includes, as the essential ingredients, a solder powder, silver nanoparticles coated with a coating material and a solvent, and additionally includes at least one ingredient selected from the group consisting of selenium metal, oxide film inhibitors and oxide film removers. This bonding and sealing material can easily form under mild conditions a metallic adhesive layer having good hermetic sealability and UV resistance of the sort desired when sealing a short-wavelength light-emitting device such as a UV-LED, and can be stably used over a long period of time.

The present disclosure relates to an Ag paste composition and a bonding film produced using same, the Ag paste composition being coated on a first object, and the first object being pressure sintered toward a second object side, thereby forming a sintered bonding layer between the first object and the second object, wherein the Ag paste composition comprises 90˜99 wt % of Ag powder, and 1˜10 wt % of an organic binder. The present disclosure controls the specific surface area and grain shape of the Ag powder, even without applying a spherical nanoparticle powder, and thus has the advantages of lowering a bond temperature and increasing bond density, thereby enabling the improvement of bond strength and reliability.

A system for forming a hollow modular candle filter includes: a first filter portion having at least one open end; a hollow second filter portion having at least one open end; a sleeve configured to fit within the open end of the first filter portion and the open end of the second filter portion; and an adhesive configured to bind the sleeve to each of the first filter portion and the second filter portion.