A semiconductor device, including a conductive plate having a front surface that includes a plurality of bonding regions and a plurality of non-bonding regions in peripheries of the bonding regions, a plurality of semiconductor elements mounted on the conductive plate in the bonding regions, and a resin encapsulating therein at least the plurality of semiconductor elements and the front surface of the conductive plate. The conductive plate has, at the front surface thereof in the non-bonding regions, a plurality of holes.

A bonding structure is a bonding structure which bonds a light emitting element and a substrate and includes a first electrode formed on the light emitting element, a second electrode formed on the substrate, and a bonding layer which bonds the first electrode and the second electrode, and the bonding layer contains a first bonding metal component and a second bonding metal component different from the first bonding metal component.

A semiconductor device includes: a multilayer substrate which includes a circuit board and an insulating plate on which the circuit board is formed; and a contact part having a cylindrical hollow hole therein and an open end bonded to a bonding area on the front surface of the circuit board via bonding material. In the case of this semiconductor device, wettability of a contact area of the contact part with respect to the bonding material is approximately equal to wettability of at least the bonding area of the circuit board with respect to the bonding material. Thus, the rising of the bonding material into the hollow hole of the contact part during heating performed when the contact part is bonded to the circuit board is reduced.

A chip package and manufacturing method is disclosed. In one example, the method includes forming a carrier wafer with a plurality of trenches, each trench being at least partially covered with an electrically conductive sidewall coating. A semiconductor wafer is bonded on a front side of the carrier wafer. An electrically conductive connection structure is formed, including at least partially bridging a gap between the electrically conductive sidewall coating and an integrated circuit element of a respective one of the electronic chips. Material on a backside of the carrier wafer is removed to singularize the bonded wafers at the trenches into a plurality of semiconductor devices.

A chip package and manufacturing method is disclosed. In one example, the method includes forming a carrier wafer with a plurality of trenches, each trench being at least partially covered with an electrically conductive sidewall coating. A semiconductor wafer is bonded on a front side of the carrier wafer. An electrically conductive connection structure is formed, including at least partially bridging a gap between the electrically conductive sidewall coating and an integrated circuit element of a respective one of the electronic chips. Material on a backside of the carrier wafer is removed to singularize the bonded wafers at the trenches into a plurality of semiconductor devices.

Provided is a method for manufacturing a semiconductor device that improves the reliability of the semiconductor device under thermal stress and the assembly performance of the semiconductor device in manufacturing steps. The method includes the following: forming a first electrode by depositing a first conductive film onto one main surface of a semiconductor substrate and patterning the first conductive film; forming a first metal film corresponding to a pattern of the first electrode onto the first electrode; forming a second electrode by depositing a second conductive film onto the other main surface of the semiconductor substrate; forming a second metal film thinner than the first metal film onto the second electrode; and collectively forming a third metal film onto each of the first metal film and the second metal film by electroless plating.

Provided is a method for manufacturing a semiconductor device that improves the reliability of the semiconductor device under thermal stress and the assembly performance of the semiconductor device in manufacturing steps. The method includes the following: forming a first electrode by depositing a first conductive film onto one main surface of a semiconductor substrate and patterning the first conductive film; forming a first metal film corresponding to a pattern of the first electrode onto the first electrode; forming a second electrode by depositing a second conductive film onto the other main surface of the semiconductor substrate; forming a second metal film thinner than the first metal film onto the second electrode; and collectively forming a third metal film onto each of the first metal film and the second metal film by electroless plating.

Techniques are employed to mitigate the anchoring effects of cavity sidewall adhesion on an embedded conductive interconnect structure, and to allow a lower annealing temperature to be used to join opposing conductive interconnect structures. A vertical gap may be disposed between the conductive material of an embedded interconnect structure and the sidewall of the cavity to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material. Additionally or alternatively, one or more vertical gaps may be disposed within the bonding layer, near the embedded interconnect structure to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material.

Techniques are employed to mitigate the anchoring effects of cavity sidewall adhesion on an embedded conductive interconnect structure, and to allow a lower annealing temperature to be used to join opposing conductive interconnect structures. A vertical gap may be disposed between the conductive material of an embedded interconnect structure and the sidewall of the cavity to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material. Additionally or alternatively, one or more vertical gaps may be disposed within the bonding layer, near the embedded interconnect structure to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material.

A chip package and manufacturing method is disclosed. In one example, the method includes forming a carrier wafer with a plurality of trenches, each trench being at least partially covered with an electrically conductive sidewall coating. A semiconductor wafer is bonded on a front side of the carrier wafer. An electrically conductive connection structure is formed, including at least partially bridging a gap between the electrically conductive sidewall coating and an integrated circuit element of a respective one of the electronic chips. Material on a backside of the carrier wafer is removed to singularize the bonded wafers at the trenches into a plurality of semiconductor devices.