An object of the present technology is to prevent damage in a bonded portion between a semiconductor chip and a substrate in a semiconductor device in which the semiconductor chip is mounted on the substrate.

A terminal is disposed between an electrode of an element and an electrode of a substrate on which the element is mounted, and electrically connects the electrode of the element and the electrode of the substrate. The terminal includes a plurality of unit lattices and a coupling portion. The unit lattices included in the terminal are formed by bonding a plurality of beams in a cube shape. The coupling portion included in the terminal couples adjacent unit lattices among the plurality of unit lattices.

Packaged semiconductor devices are disclosed. In some embodiments, a packaged semiconductor device includes a substrate and a plurality of integrated circuit dies coupled to the substrate. The device also includes a molding material disposed over the substrate between adjacent ones of the plurality of integrated circuit dies. A cap layer is disposed over the molding material and the plurality of integrated circuit dies, wherein the cap layer comprises an electrically conductive material that directly contacts the molding material and each of the plurality of integrated circuit dies.

Packaged semiconductor devices are disclosed. In some embodiments, a packaged semiconductor device includes a substrate and a plurality of integrated circuit dies coupled to the substrate. The device also includes a molding material disposed over the substrate between adjacent ones of the plurality of integrated circuit dies. A cap layer is disposed over the molding material and the plurality of integrated circuit dies, wherein the cap layer comprises an electrically conductive material that directly contacts the molding material and each of the plurality of integrated circuit dies.

A semiconductor package of a pin-grid-array type includes a bump pad on a first substrate, a metal socket on a second substrate, a core material for reverse reflow on the bump pad, and solder paste or a solder bump forming a solder layer on the core material for reverse reflow. The solder paste or the solder bump is in contact with the bump pad. The core material for reverse reflow and the solder paste or the solder bump bonded to the core material for reverse reflow are used as a pin and detachably attached to the metal socket. The core material for reverse reflow includes a core, a first metal layer directly coated on the core, and a second metal layer directly coated on the first metal layer.

A semiconductor package of a pin-grid-array type includes a bump pad on a first substrate, a metal socket on a second substrate, a core material for reverse reflow on the bump pad, and solder paste or a solder bump forming a solder layer on the core material for reverse reflow. The solder paste or the solder bump is in contact with the bump pad. The core material for reverse reflow and the solder paste or the solder bump bonded to the core material for reverse reflow are used as a pin and detachably attached to the metal socket. The core material for reverse reflow includes a core, a first metal layer directly coated on the core, and a second metal layer directly coated on the first metal layer.

Microelectronic assemblies fabricated using hybrid manufacturing for integrating photonic and electronic components, as well as related devices and methods, are disclosed herein. As used herein, “hybrid manufacturing” refers to fabricating a microelectronic assembly by bonding at least two IC structures fabricated using different manufacturers, materials, or manufacturing techniques. Before bonding, at least one IC structure may include photonic components such as optical waveguides, electro-optic modulators, and monolithically integrated lenses, and at least one may include electronic components such as electrically conductive interconnects, transistors, and resistors. One or more additional electronic and/or photonic components may be provided in one or more of these IC structures after bonding. For example, an interconnect implemented as an electrically conductive via or a waveguide implemented as a dielectric via may be provided after bonding to extend through one or more of the bonded IC structures.

Microelectronic assemblies fabricated using hybrid manufacturing for integrating photonic and electronic components, as well as related devices and methods, are disclosed herein. As used herein, “hybrid manufacturing” refers to fabricating a microelectronic assembly by bonding at least two IC structures fabricated using different manufacturers, materials, or manufacturing techniques. Before bonding, at least one IC structure may include photonic components such as optical waveguides, electro-optic modulators, and monolithically integrated lenses, and at least one may include electronic components such as electrically conductive interconnects, transistors, and resistors. One or more additional electronic and/or photonic components may be provided in one or more of these IC structures after bonding. For example, an interconnect implemented as an electrically conductive via or a waveguide implemented as a dielectric via may be provided after bonding to extend through one or more of the bonded IC structures.

An electronic device with stud bumps is disclosed. In an embodiment an electronic device includes a carrier board having an upper surface and an electronic chip mounted on the upper surface, the electronic chip having a mounting side facing the upper surface of the carrier board, a top side facing away from the upper surface, and sidewalls connecting the mounting side to the top side, wherein the electronic chip has equal to or less than 5 stud bumps per square millimeter of a base area of the mounting side, wherein the carrier board has at least one recess in the upper surface, and wherein at least one of the stud bumps reaches into the recess.

An electronic device with stud bumps is disclosed. In an embodiment an electronic device includes a carrier board having an upper surface and an electronic chip mounted on the upper surface, the electronic chip having a mounting side facing the upper surface of the carrier board, a top side facing away from the upper surface, and sidewalls connecting the mounting side to the top side, wherein the electronic chip has equal to or less than 5 stud bumps per square millimeter of a base area of the mounting side, wherein the carrier board has at least one recess in the upper surface, and wherein at least one of the stud bumps reaches into the recess.

Disclosed herein is a semiconductor device including a conductive member that has a main surface facing in a thickness direction, a semiconductor element that has a plurality of pads facing the main surface, a plurality of electrodes that are individually formed with respect to the plurality of pads and protrude from the plurality of pads toward the main surface, and a bonding layer for electrically bonding the main surface to the plurality of electrodes. The bonding layer includes a first region having conductivity and a second region having electrical insulation. The first region includes a metal portion. At least a part of the second region includes a resin portion.