A joined structure which is configured such that a space between adjacent substrates is filled with a filling material. The joined structure includes a first substrate having a first conductor formed on a surface of the first substrate, a second substrate having a second conductor formed on a surface of the second substrate, arranged so that a surface of the first substrate faces a surface of the second substrate, a connecting conductor which electrically connects the first conductor and the second conductor, and a filling material between the first substrate and the second substrate. The filling material is formed into such a shape that a space is provided which corresponds to at least one of the first conductor, the second and the connecting conductor.

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.

The present invention aims to provide a method for producing a semiconductor device, the method being capable of achieving high reliability by suppressing voids. The present invention also aims to provide a flip-chip mounting adhesive for use in the method for producing a semiconductor device. The present invention relates to a method for producing a semiconductor device, including: step 1 of positioning a semiconductor chip on a substrate via an adhesive, the semiconductor chip including bump electrodes each having an end made of solder; step 2 of heating the semiconductor chip at a temperature of the melting point of the solder or higher to solder and bond the bump electrodes of the semiconductor chip to an electrode portion of the substrate, and concurrently to temporarily attach the adhesive; and step 3 of removing voids by heating the adhesive under a pressurized atmosphere, wherein the adhesive has an activation energy ΔE of 100 kJ/mol or less, a reaction rate of 20% or less at 2 seconds at 260° C., and a reaction rate of 40% or less at 4 seconds at 260° C., as determined by differential scanning calorimetry and Ozawa method.

Method for manufacturing an RFID tag comprising an IC and an antenna. The method comprising the steps of providing an antenna made of a soldering material, which antenna is at least partly covered with a hot melt adhesive in solid form; heating the antenna to a temperature above its melting point, wherein the heated parts of the antenna and the hot melt adhesive melt, placing an IC in a predetermined position which position is suitable for the IC to connect to the antenna; pressing the IC and antenna together, such that, an electrical connection between the IC and the antenna is established; and cooling RFID tag, such that the hot melt adhesive and the antenna solidify, wherein a soldered joint between the IC and the antenna is achieved and the hot melt adhesive surrounds the joint between the IC and the antenna.

A semiconductor package includes a plurality of semiconductor chips on a substrate. The semiconductor chips include a first semiconductor chip, a second semiconductor chip, and a third semiconductor chip that are sequentially stacked on the substrate. The semiconductor package further includes a plurality of non-conductive layers between the substrate and the first semiconductor chip and between adjacent semiconductor chips among the semiconductor chips. The semiconductor chips include smaller widths as a distance from the substrate increases. Each of the non-conductive layers includes an extension protruding outward from a side surface of an overlying one of the semiconductor chips.

Microelectronic devices with an embedded die substrate on an interposer are described. For example, a microelectronic device includes a substrate housing an embedded die. At least one surface die is retained above a first outermost surface of the substrate. An interposer is retained proximate a second outermost surface of the substrate.

Some implementations described herein provide a semiconductor structure. The semiconductor structure includes a first wafer including a first metal structure within a body of the first wafer. The semiconductor structure also includes a second wafer including a second metal structure within a body of the second wafer, where the first wafer is coupled to the second wafer at an interface. The semiconductor structure further includes a metal bonding structure coupled to the first metal structure and the second metal structure and extending through the interface.

Disclosed is a microelectronic device assembly comprising a substrate having conductors exposed on a surface thereof. Two or more microelectronic devices are stacked on the substrate and the components are connected with conductive material in preformed holes in dielectric material in the bond lines aligned with TSVs of the devices and the exposed conductors of the substrate. Methods of fabrication are also disclosed.

In accordance with an embodiment of the present invention, a semiconductor device includes a semiconductor chip having a first side and an opposite second side, and a chip contact pad disposed on the first side of the semiconductor chip. A dielectric liner is disposed over the semiconductor chip. The dielectric liner includes a plurality of openings over the chip contact pad. A interconnect contacts the semiconductor chip through the plurality of openings at the chip contact pad.