A joined body includes a first substrate, a second substrate which faces the first substrate, and a joining film which joins the first substrate to the second substrate, wherein the joining film has a first region and a second region, and in a plan view of the first substrate, the first region has a higher metal nanoparticle density than the second region.

A package structure is provided. The package structure includes a chip-containing structure over a substrate and a first adhesive element directly above the chip-containing structure. The first adhesive element has a first thermal conductivity. The package structure also includes multiple second adhesive elements directly above the chip-containing structure. The second adhesive elements are spaced apart from each other, each of the second adhesive elements has a second thermal conductivity, and the second thermal conductivity is greater than the first thermal conductivity. The package structure further includes a protective lid attached to the chip-containing structure through the first adhesive element and the second adhesive elements. The protective lid extends across opposite sidewalls of the chip-containing structure.

A semiconductor package including an interposer substrate, first to third semiconductor chips on the interposer substrate to face each other, an underfill part between each of the first to third semiconductor chips and the interposer substrate, a first side-fill part extending upward from a lower end of side walls of the first to third semiconductor chips, and a second side-fill part between the side walls of the first to third semiconductor chips and extending from the first side-fill part to an upper end of the side walls of the first to third semiconductor chips may be provided.

Structures and formation methods of a chip package structure are provided. The chip package structure includes an interposer substrate including first and second die regions that are separated by a gap region. The chip package structure also includes first and second semiconductor dies respectively arranged over the first and second die regions. In addition, the chip package structure includes first and second gap-filling layers formed over the gap region and separated from one another, and a third gap-filling layer over the gap region and between the first and second gap-filling layers. The Young's modulus of the third gap-filling layer is less than the Young's modulus of the first gap-filling layer and the Young's modulus of the second gap-filling layer.

A semiconductor package including an interposer substrate, first to third semiconductor chips on the interposer substrate to face each other, an underfill part between each of the first to third semiconductor chips and the interposer substrate, a first side-fill part extending upward from a lower end of side walls of the first to third semiconductor chips, and a second side-fill part between the side walls of the first to third semiconductor chips and extending from the first side-fill part to an upper end of the side walls of the first to third semiconductor chips may be provided.

A semiconductor component support is provided which includes a component support portion for a semiconductor component to be mounted on the semiconductor component support portion. The component support portion includes a metal part that includes an opening in plan view. The opening of the metal part includes first and second sections. The second section communicates with the first section, and is arranged outside the first section. The second section is wider than the first section. The first section can be at least partially positioned directly under a mount-side main surface of the semiconductor component.

Structures and formation methods of a chip package structure are provided. The method includes mounting semiconductor dies over die regions of an interposer substrate. The adjacent die regions are separated from one another by a gap region of the interposer substrate. The method also includes forming first underfill material layers and a second gap-filling layer over the interposer substrate corresponding to the gap region. The method further includes forming an encapsulating layer over the interposer substrate to surround the semiconductor dies, the first underfill material layers, and the second underfill material layer. The gap region has ends and the first underfill material layers is formed adjacent to the ends of the gap region. The Young's modulus of the second underfill material layer is less than that of the first underfill material layers.

A semiconductor package includes a substrate defining a first trench structure and a second trench structure in an upper surface of the substrate; a semiconductor chip on the substrate; and an underfill filling a space between the substrate and the semiconductor chip. The first trench structure and the second trench structure surround the semiconductor chip. The first trench structure includes at least one first line pattern extending along at least one side surface of the semiconductor chip. The second trench structure includes at least one second line pattern extending along at least one other side surface of the semiconductor chip. A horizontal width of the at least one first line pattern is greater than a horizontal width of the at least one second line pattern.

An electronic component has a circuit board with a main surface, a chip having a sensor facing the main surface, bump electrodes disposed between the main surface and the chip so as to be placed inside of the edges of the chip in a plan view of the main surface, a dam provided between the main surface and the chip so as to extend at least from the edges of the chip to outer positions of the bump electrodes in a plan view of the main surface, and an under-fill material provided at least in a clearance between the dam and the chip. Between the main surface and the sensor, a space is formed in a region enclosed by the bump electrodes in a plan view of the main surface. The under-fill material is disposed outside of the space in a plan view of the main surface.

A semiconductor device including: a die paddle having an upper surface; a solder layer disposed on the upper surface of the die paddle; and a die disposed on the solder layer, so that the solder layer is between the die paddle and the die; the solder layer includes a plurality of spacers configured to be, during production of the semiconductor device prior to hardening of the solder layer, movable in relation to the die paddle; and the die paddle includes a plurality of recesses in the upper surface of the die paddle, and the plurality of recesses is configured to receive the plurality of spacers, so that the plurality of spacers is embedded within the plurality of recesses.