It is an object of the present invention to provide a wireless chip of which mechanical strength can be increased. Moreover, it is an object of the present invention to provide a wireless chip which can prevent an electric wave from being blocked. The invention is a wireless chip in which a layer having a thin film transistor is fixed to an antenna by an anisotropic conductive adhesive or a conductive layer, and the thin film transistor is connected to the antenna. The antenna has a dielectric layer, a first conductive layer, and a second conductive layer. The dielectric layer is sandwiched between the first conductive layer and the second conductive layer. The first conductive layer serves as a radiating electrode and the second conductive layer serves as a ground contact body.

A three-dimensional (3D) bonded semiconductor structure is provided in which a first bonding oxide layer of a first semiconductor structure is bonded to a second bonding oxide layer of a second semiconductor structure. Each of the first and second bonding oxide layers has a metallic bonding structure embedded therein, wherein each metallic bonding structure contains a columnar grain microstructure. Furthermore, at least one columnar grain extends across a bonding interface that is present between the metallic bonding structures. The presence of the columnar grain microstructure in the metallic bonding structures, together with at least one columnar grain microstructure extending across the bonding interface between the two bonded metallic bonding structures, can provide a 3D bonded structure having mechanical bonding strength and electrical performance enhancements.

A method of manufacturing a bond pad structure may include depositing an aluminum-copper (AlCu) layer over a dielectric layer; and depositing an aluminum-chromium (AlCr) layer directly over the AlCu layer.

A packaged semiconductor device is made by forming a conductive pad on an external surface of an integrated circuit device, forming a passivation layer over the conductive pad, removing a portion of the passivation layer over a bond area on the conductive pad, forming a sacrificial anode around a majority of a periphery surrounding the bond area, forming a conductive bond in the bond area, and forming an encapsulating material around the conductive bond and an exposed portion of the sacrificial anode.

A device and methods of forming the device are disclosed. A substrate with a circuits component and a dielectric layer with interconnects is provided. A pad level dielectric layer is formed over the dielectric layer. A primary passivation layer is formed over the pad level dielectric layer with pad interconnects. The substrate is subjected to an alloying process. During the alloying process, the primary passivation layer prevents or reduces formation of hillocks on surfaces of the pad interconnects to improve surface smoothness of the pad interconnects. Pad openings are formed in the pad level dielectric layer to expose top surfaces of the pad interconnects. A cap dielectric layer is formed on the substrate and lines the primary passivation layer as well as the exposed top surfaces of the pad interconnects. A final passivation layer is formed on the substrate and covers the cap dielectric layer. The final passivation layer is patterned to form final passivation openings corresponding to the pad openings.

The present invention includes: preparing a semiconductor substrate having a first main surface and a second main surface that is located on an opposite side of the first main surface; forming a first electrode on the first main surface; forming a solder-bonding metal film (a first solder-bonding metal film) on the first electrode; forming a sacrificial film on the first solder-bonding metal film; grinding the second main surface after forming the sacrificial film; performing heat treatment after the grinding (forming an element structure on the third main surface side); removing the sacrificial film after the performing heat treatment; and solder-bonding the first solder-bonding metal film and a first external electrode.

A method of forming solder bumps includes preparing a substrate having a surface on which a plurality of electrode pads are formed, forming a resist layer on the substrate, the resist layer having a plurality of openings, each of the openings being aligned with a corresponding electrode pad of the plurality of electrode pads, forming a conductive pillar in each of the openings of the resist layer, forming conductive layers to cover at least side walls of the resist layer in the openings to block gas emanating from the resist layer, filling molten solder in each of the openings in which the conductive layers has been formed and removing the resist layer.

A semiconductor structure and its fabrication method are provided. The fabrication method includes: providing a base substrate including a wiring region and an isolation region. A patterned layer is formed on the isolation region of the base substrate and the patterned layer exposes the wiring region of the base substrate. After forming the patterned layer, a redistribution layer is formed on the wiring region of the based substrate exposed by the patterned layer. A protective layer is formed on the redistribution layer, and after forming the protective layer, the patterned layer is removed.

A semiconductor device and method of manufacture are provided. In an embodiment a first semiconductor device and a second semiconductor device are formed within a semiconductor wafer and a scribe region between the first semiconductor device and the second semiconductor device is patterned. A singulation process is then utilized within the scribe region to singulate the first semiconductor device from the second semiconductor device. The first semiconductor device and the second semiconductor device are then bonded to a second semiconductor substrate and thinned in order to remove extension regions from the first semiconductor device and the second semiconductor device.

To provide a semiconductor device 100 including a semiconductor element with a less warped chip. A semiconductor device manufacturing method include: bonding a rear surface of a chip having electrodes on both sides thereof to a front surface of a substrate; providing, to the front surface of the substrate to which the chip is bonded, a plating protective film having an opening at a position which is on the front surface of the chip and corresponds to an electrode at which plating is to be formed, after the bonding; plating the electrode of the chip after the providing; and removing the plating protective film from the substrate, after the plating.