In one example, a semiconductor device includes a substrate having a substrate first side, a substrate second side opposite to the substrate first side, and a conductive structure including internal terminals over the substrate first side; and external terminals over the substrate second side and coupled to the internal terminals. An electronic component includes an electronic component first side, an electronic component second side opposite to the electronic component first side, and an electronic component lateral side connecting the electronic component first side to the electronic component second side. The electronic component second side is coupled to one or more of the internal terminals. A guide structure is over the substrate first side and can include an inner portion that is laterally inward from the electronic component lateral side and an outer portion that is laterally outward from the electronic component lateral side. An underfill is interposed between the electronic component second side and the substrate first side and is over the guide structure. Other examples and related methods are also disclosed herein.

One or more embodiments are directed to semiconductor packages and methods in which one or more electrical components are positioned between a semiconductor die and a surface of a substrate. In one embodiment, a semiconductor package includes a substrate having a first surface. One or more electrical components are electrically coupled to electrical contacts on the first surface of the substrate. A semiconductor die is positioned on the one or more electrical components, and the semiconductor die has an active surface that faces away from the substrate. An adhesive layer is on the first surface of the substrate and on the one or more electrical components, and the semiconductor die is spaced apart from the one or more electrical components by the adhesive layer. Wire bonds are provided that electrically couples the active surface of the semiconductor die to the substrate.

There is provided a semiconductor device including: a semiconductor element; a support substrate configured to support the semiconductor element; an intermediate metal layer interposed between the semiconductor element and the support substrate in a thickness direction of the support substrate, wherein the semiconductor element and the intermediate metal layer are bonded by solid phase diffusion bonding; and a first positioning portion including a portion of the semiconductor element and a first portion of the intermediate metal layer and configured to suppress relative movement between the semiconductor element and the intermediate metal layer.

A semiconductor chip (6) having flexibility is bonded to a heat radiation material (4) with solder. The semiconductor chip (6) is pressed by a tip of a pressing member (9,11) from an upper side. As a result, convex warpage of the semiconductor chip (6) can be suppressed. Furthermore, since voids can be prevented from remaining in the solder (7), the heat radiation of the semiconductor device can be enhanced.

According to one embodiment, the electrode pads are provided at a surface of the substrate. The metal pad is provided at the surface of the substrate. The electronic component is mounted to the surface of the substrate. The electronic component includes a plurality of opposing electrodes. The opposing electrodes oppose the electrode pads in a direction toward the surface direction and are electrically connected to the electrode pads. The positioning component is fixed to the metal pad. A gap between the positioning component and the electronic component in an in-plane direction of the surface of the substrate is shorter than a minimum distance of the electrode pads.

Electronic device comprising a support substrate having a mounting face and an electronic chip having a rear face bonded on the mounting face by a volume of adhesive, wherein the support substrate comprises a plurality of wedging elements projecting from the mounting face so as to hold the chip bearing on contact areas of the wedging elements in a position substantially parallel to the mounting face of the support substrate.

In a soldering structure, a power module having the same, and a method for manufacturing the power module configured for constantly determining a height of a power module when the power module is manufactured, the soldering structure may include a soldering target portion; a metal layer including a bonding surface having a bonding region in which the soldering target portion is bonded by solder; and at least one wire located in the solder within the bonding region.

In an embodiment, a package includes: an interposer having a first side; a first integrated circuit device attached to the first side of the interposer; a second integrated circuit device attached to the first side of the interposer; an underfill disposed beneath the first integrated circuit device and the second integrated circuit device; and an encapsulant disposed around the first integrated circuit device and the second integrated circuit device, a first portion of the encapsulant extending through the underfill, the first portion of the encapsulant physically disposed between the first integrated circuit device and the second integrated circuit device, the first portion of the encapsulant being planar with edges of the underfill and edges of the first and second integrated circuit devices.

A semiconductor chip (6) having flexibility is bonded to a heat radiation material (4) with solder. The semiconductor chip (6) is pressed by a tip of a pressing member (9,11) from an upper side. As a result, convex warpage of the semiconductor chip (6) can be suppressed. Furthermore, since voids can be prevented from remaining in the solder (7), the heat radiation of the semiconductor device can be enhanced.

A method for forming a semiconductor device is provided. The method includes providing a substrate. The method includes forming a mask layer over a surface of the substrate. The mask layer has an opening over a portion of the surface. The method includes depositing a conductive layer over the surface and the mask layer. The method includes removing the mask layer and the conductive layer over the mask layer. The conductive layer remaining after the removal of the mask layer and the conductive layer over the mask layer forms a conductive pad. The method includes bonding a device to the conductive pad through a solder layer. The conductive pad is embedded in the solder layer.