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 member for semiconductor device includes a metal portion configured to be bonded to another member by solder, and a treated coating covering a surface of the metal portion, the treated coating including a treatment agent. The treated coating vaporizes at a temperature lower than or equal to a solidus temperature of the solder.

According to one embodiment, a semiconductor device includes a first semiconductor element having a first surface, a second semiconductor element having a lower surface bonded to the first surface of the first semiconductor element, a gel-like silicone that covers an upper surface of the second semiconductor element, and a resin portion that covers the gel-like silicone and the first surface of the first semiconductor element.

Described examples include a packaged device including a first object and a second object spaced from each other by a gap, each object having a first surface and an opposite second surface, the first surfaces of the first object and the second object including first terminals. A structure includes at least two conductors embedded in a dielectric casing consolidating a configuration and organization of the at least two conductors, the at least two conductors having end portions un-embedded by the dielectric casing. An end portion of at least one of the at least two conductors is electrically connected to a first terminal of the first object, and an opposite end portion of the at least one of the at least two conductors is electrically connected to a respective first terminal of the second object, the at least two conductors electrically connecting the first object and the second object.

A method for bonding of a first solid substrate to a second solid substrate which contains a first material with the following steps, especially the following sequence: formation or application of a function layer which contains a second material to the second solid substrate, making contact of the first solid substrate with the second solid substrate on the function layer, pressing together the solid substrates for forming a permanent bond between the first and second solid substrate, at least partially reinforced by solid diffusion and/or phase transformation of the first material with the second material, an increase of volume on the function layer being caused.

A solder joint layer has a structure in which plural fine-grained second crystal sections (22) precipitate at crystal grain boundaries between first crystal sections (21) dispersed in a matrix. The first crystal sections (21) are Sn crystal grains containing tin and antimony in a predetermined proportion. The second crystal sections (22) are made up of a first portion containing a predetermined proportion of Ag atoms with respect to Sn atoms, or a second portion containing a predetermined proportion of Cu atoms with respect to Sn atoms, or both. The solder joint layer may have third crystal sections (23) which are crystal grains that contain a predetermined proportion of Sb atoms with respect to Sn atoms. As a result, solder joining is enabled at a low melting point, and a highly reliable solder joint layer having a substantially uniform metal structure can be formed.

There is provided a method for producing a member for semiconductor device which can reduce generation of a large number of voids in a solder-bonded portion without increasing production cost. The method includes the step of preparing a first member including a metal portion capable of being bonded by solder and the step of coating the surface of the metal portion of the first member with a treatment agent to form a treated coating which vaporizes at a temperature lower than or equal to the solidus temperature of the solder.

The disclosed technology generally relates to semiconductor wafer bonding, and more particularly to direct bonding by contacting surfaces of the semiconductor wafers. In one aspect, a method for bonding a first semiconductor substrate to a second semiconductor substrate by direct bonding is described. The substrates are both provided on their contact surfaces with a dielectric layer, followed by a CMP step for reducing the roughness of the dielectric layer. Then a layer of SiCN is deposited onto the dielectric layer, followed by a CMP step which reduces the roughness of the SiCN layer to the order of 1 tenth of a nanometer. Then the substrates are subjected to a pre-bond annealing step and then bonded by direct bonding, possibly preceded by one or more pre-treatments of the contact surfaces, and followed by a post-bond annealing step, at a temperature of less than or equal to 250 C. It has been found that the bond strength is excellent, even at the above named annealing temperatures, which are lower than presently known in the art.

According to one embodiment, a semiconductor device includes a first semiconductor element having a first surface, a second semiconductor element having a lower surface bonded to the first surface of the first semiconductor element, a gel-like silicone that covers an upper surface of the second semiconductor element, and a resin portion that covers the gel-like silicone and the first surface of the first semiconductor element.

A multilayer composite bonding material for transient liquid phase bonding a semiconductor device to a metal substrate includes thermal stress compensation layers sandwiched between a pair of bonding layers. The thermal stress compensation layers may include a core layer with a first stiffness sandwiched between a pair of outer layers with a second stiffness that is different than the first stiffness such that a graded stiffness extends across a thickness of the thermal stress compensation layers. The thermal stress compensation layers have a melting point above a sintering temperature and the bonding layers have a melting point below the sintering temperature. The graded stiffness across the thickness of the thermal stress compensation layers compensates for thermal contraction mismatch between the semiconductor device and the metal substrate during cooling from the sintering temperature to ambient temperature.