A package includes a chip formed in a first area of the package and a molding compound formed in a second area of the package adjacent to the first area. A first polymer layer is formed on the chip and the molding compound, a second polymer layer is formed on the first polymer layer, and a plurality of interconnect structures is formed between the first polymer layer and the second polymer layer. A metal-insulator-metal (MIM) capacitor is formed on the second polymer layer and electrically coupled to at least one of the plurality of interconnect structures. A metal bump is formed over and electrically coupled to at least one of the plurality of interconnect structures.

A light emitting device including a substrate, a first conductivity-type semiconductor layer, a mesa including a second conductivity-type semiconductor layer and an active layer, first and second contact electrodes respectively contacting the first and second conductivity-type semiconductor layers, a passivation layer covering the first and second contact electrodes, the mesa, and including first and second openings, and first and second bump electrodes electrically connected to the first and second contact electrodes through the first and second openings, respectively, in which the first and second bump electrodes are disposed on the mesa, the passivation layer is disposed between the first bump electrode and the second contact electrode, the first contact electrode includes a reflective material, and a portion of the first opening is surrounded with a side surface of the mesa, and another portion of the first opening is not surrounded with the side surface of the mesa.

Disclosed are a display substrate, a preparation method therefor, and a display device. The display substrate includes a display region and a binding region on one side of the display region. The binding region includes a binding structure layer disposed on a base. The binding structure layer includes a composite insulating layer disposed on the base. The binding region further includes a step structure formed by the base and the composite insulating layer. Heights of steps in the step structure decrease sequentially in the direction away from the display region. In the step structure, the base forms a first step having the smallest height. The binding structure layer further includes a signal connection wire having at least a portion thereof the disposed on the step structure and located on the first step. An opening exposing the signal connection wire is provided on the base at the first step.

In a layered bonding material 10, a coefficient of linear expansion of a base material 11 is 5.5 to 15.5 ppm/K and a first surface and a second surface of the base material 11 are coated with pieces of lead-free solder 12a and 12b.

Provided is a method for manufacturing a conductive pillar capable of bonding a substrate and a bonding member with high bonding strength via a bonding layer without employing an electroplating method, and a method for manufacturing a bonded structure by employing this method. A method for manufacturing a conductive pillar 1 includes, in sequence, the steps of forming a resist layer 16 on a substrate 11 provided with an electrode pad 13, the resist layer 16 including an opening portion 16a on the electrode pad 13, forming a thin Cu film 17 by sputtering or evaporating Cu on a surface of the substrate 11 provided with the resist layer 16 including the opening portion 16a, filling the opening portion 16a with a fine particle copper paste 12c, and sintering the fine particle copper paste 12c by heating the substrate 11 filled with the fine particle copper paste 12c.

A cryo-compatible quantum computing arrangement includes a microelectronic quantum computing component having a substrate structure, a plurality of first contact elements and a plurality of conductive feedthroughs through the substrate structure, wherein the conductive feedthroughs are electrically connected on a first main surface area of the substrate structure to associated first contact elements of the microelectronic quantum computing component, and a further microelectronic component having a plurality of second contact elements, wherein on a second main surface area of the substrate structure, the conductive feedthroughs are electrically connected to associated second contact elements of the further microelectronic component, and wherein the conductive feedthroughs each include, between the first and second contact elements, a layer element including a first material that is superconducting at a quantum computing operating temperature, and a filling element including a second material that is electrically conductive.

An object is to provide a technique capable of suppressing generation of a crack in a molding resin and suppressing entry of moisture from the outside. A semiconductor device includes a heat spreader, a semiconductor element provided on an upper surface of the heat spreader, an insulating sheet provided on a lower surface of the heat spreader, a lead frame joined to an upper surface of the semiconductor element via solder, and a molding resin that seals one end side of the lead frame, the semiconductor element, the heat spreader, and the insulating sheet. A hole is formed from an upper surface of the molding resin to a joining surface of the lead frame with the semiconductor element, and the hole is filled with a low Young's modulus resin having a Young's modulus lower than that of the molding resin.

A semiconductor device includes a semiconductor element, a first wiring member, a second wiring member, and a terminal. The semiconductor element includes a first main electrode and a second main electrode on a side opposite from the first main electrode. The first wiring member is connected to the first main electrode. The terminal has a first terminal surface connected to the second main electrode and a second terminal surface. The second terminal has four sides. Two of the four sides are parallel to a first direction intersecting the thickness direction, and other two sides of the four sides are parallel to a second direction perpendicular to the thickness direction and the first direction. The second wiring member is connected to the second terminal surface of the terminal through solder, and has a groove. The groove overlaps one or two of the four sides of the second terminal surface.

A display backplane is provided, including a base, wherein pixel circuits, bonding electrodes, and bonding connection wires are on the base; the bonding electrodes are coupled to the bonding connection wires in a one-to-one correspondence; the bonding electrodes and the bonding connection wires are on two opposite surfaces of the base; the pixel circuits and the bonding connection wires are on a same side of the base; one end of each bonding connection wire is coupled to the bonding electrode through the first via in the base; the other end of each of at least some bonding connection wires is coupled to the pixel circuit; and an orthographic projection of at least one of the bonding electrodes and the bonding connection wires on the base is not coincident with an orthographic projection of the pixel circuit on the base.

Provided is a semiconductor module including a main circuit portion, a plurality of circuit electrodes, a plurality of main terminals, and a plurality of wires, in each of semiconductor chips, transistor portions and diode portions have a longitudinal side in a second direction, each of semiconductor chips has a plurality of end sides including a gate-side end side, each of the gate-side end sides is arranged facing a same side in a top view, the plurality of main terminals are arranged on a same side in relation to the main circuit portion so as not to sandwich the main circuit portion in a top view, each of the plurality of wires has a bonding portion, and a longitudinal direction of the bonding portion has an angle in relation to the second direction.