A method for manufacturing a semiconductor apparatus, including preparing a first substrate provided with a pad optionally having a plug and a second substrate or device provided with a plug, forming a solder ball on at least one of the pad or plug of first substrate and the plug of second substrate or device, covering at least one of a pad-forming surface of first substrate and a plug-forming surface of second substrate or device with a photosensitive insulating layer, forming an opening on the pad or plug of the substrate or device that has been covered with photosensitive insulating layer by lithography, pressure-bonding the second substrate or device's plug to the pad or plug of first substrate with the solder ball through the opening, electrically connecting pad or plug of first substrate to second substrate or device's plug by baking, and curing photosensitive insulating layer by baking.

A method for manufacturing a semiconductor apparatus, including preparing a first substrate provided with a pad optionally having a plug and a second substrate or device provided with a plug, forming a solder ball on at least one of the pad or plug of first substrate and the plug of second substrate or device, covering at least one of a pad-forming surface of first substrate and a plug-forming surface of second substrate or device with a photosensitive insulating layer, forming an opening on the pad or plug of the substrate or device that has been covered with photosensitive insulating layer by lithography, pressure-bonding the second substrate or device's plug to the pad or plug of first substrate with the solder ball through the opening, electrically connecting pad or plug of first substrate to second substrate or device's plug by baking, and curing photosensitive insulating layer by baking.

A method includes forming a first tacking layer on a first connection partner, arranging a first layer on the first tacking layer, forming a second tacking layer on the first layer, arranging a second connection partner on the second tacking layer, heating the tacking layers and first layer, and pressing the first connection partner towards the second connection partner, with the first layer arranged between the connection partners, such that a permanent mechanical connection is formed between the connection partners. Either the tacking layers each include a second material evenly distributed within a first material, the second material being configured to act as or to release a reducing agent, or the tacking layers each include a mixture of at least a third material and a fourth material, the materials in the mixture chemically reacting with each other under the influence of heat such that a reducing agent is formed.

Process for producing an electronic subassembly by low-temperature pressure sintering, comprising the following steps: arranging an electronic component on a circuit carrier having a conductor track, connecting the electronic component to the circuit carrier by the low-temperature pressure sintering of a joining material which connects the electronic component to the circuit carrier, characterized in that, to avoid the oxidation of the electronic component or of the conductor track, the low-temperature pressure sintering is carried out in a low-oxygen atmosphere having a relative oxygen content of 0.005 to 0.3%.

An object is to provide highly reliable semiconductor element bonding portion and semiconductor device that have high heat resistance and improved adhesion between a bonding material and a sealing resin. Provided is a semiconductor element bonding portion in which the semiconductor element 11 and an electrically conductive plate 123a are bonded to each other by a bonding layer 10 and the bonding layer 10 includes a metal nanoparticle sintered body 101 and a coupling agent 102 including an SH group.

A method for the production of a silver sintering agent in the form of a layer-shaped silver sintering body having silver oxide surfaces and the use thereof are provided.

A semiconductor structure is provided. The semiconductor structure includes a first semiconductor device. The first semiconductor device includes a first bonding layer formed below a first substrate, a first bonding via formed through the first oxide layer and the first bonding layer, a first dummy pad formed in the first bonding layer. The semiconductor structure includes a second semiconductor device. The second semiconductor device includes a second bonding layer formed over a second substrate, a second bonding via formed through the second bonding layer, and a second dummy pad formed in the second bonding layer. The semiconductor structure includes a bonding structure between the first substrate and the second substrate, wherein the bonding structure includes the first bonding via bonded to the second bonding via and the first dummy pad bonded to the second dummy pad.

A manufacturing method includes the step of laminating a sheet assembly onto chips arranged on a processing tape, where the sheet assembly has a multilayer structure including a base and a sinter-bonding sheet and is laminated so that the sinter-bonding sheet faces the chips, and subsequently removing the base B from the sinter-bonding sheet. The chips on the processing tape are picked up each with a portion of the sinter-bonding sheet adhering to the chip, to give sinter-bonding material layer-associated chips. The sinter-bonding material layer-associated chips are temporarily secured through the sinter-bonding material layer to a substrate. The sinter-bonding material layers lying between the temporarily secured chips and the substrate are converted through a heating process into sintered layers, to bond the chips to the substrate. The semiconductor device manufacturing method is suitable for efficiently supplying a sinter-bonding material to semiconductor chips while reducing loses of the sinter-bonding material.

A method for manufacturing a semiconductor device is provided, the method including: mounting a first element on a wiring substrate, placing a first heat sink on the first element with a metal material interposed between the first heat sink and the first element, attaching the first heat sink to the first element via the metal material by heating and melting the metal material, and mounting a second element on the wiring substrate after the steps of attaching the first heat sink to the first element.

Provided are: a conductive paste in which sinterability of silver particles the conductive paste can be easily controlled by using silver particles having predetermined crystal transformation characteristics defined by an XRD analysis, and after a sintering treatment, excellent electrical conductivity and thermal conductivity can be stably obtained; and a die bonding method using the conductive paste. Disclosed is a conductive paste which includes silver particles having a volume average particle size of 0.1 to 30 μm as a sinterable conductive material, and a dispersing medium for making a paste-like form, and in which when the integrated intensity of the peak at 2θ=38°±0.2° in the X-ray diffraction chart obtainable by an XRD analysis before a sintering treatment of the silver particles is designated as S1, and the integrated intensity of the peak at 2θ=38°±0.2° in the X-ray diffraction chart obtainable by an XRD analysis after a sintering treatment (250° C., 60 minutes) of the silver particles is designated as S2, the value of S2/S1 is adjusted to a value within the range of 0.2 to 0.8.