A semiconductor structure includes: a first substrate, with a first opening being provided on a surface of first substrate; and a first bonding structure positioned in the first opening. The first bonding structure includes a first metal layer and a second metal layer with a melting point lower than that of the first metal layer. The first metal layer includes a first surface in contact with a bottom surface of the first opening and a second surface opposite to the first surface, the second surface is provided with a first groove, an area, not occupied by the first metal layer and the first groove, of the first opening constitutes a second groove, the second metal layer is formed in the first groove and the second groove, and a surface, exposed from the second groove, of the second metal layer constitutes a bonding surface of the first bonding structure.

A display device includes a first base layer including a first opening; a first barrier layer located on a surface of the first base layer, and including a second opening; and a pad electrode located on the first barrier layer and overlapping the second opening in a plan view. At least one first groove is formed at a surface of the first barrier layer, a second groove is formed at a surface of the pad electrode, and the first opening exposes the at least one first groove and the second groove.

In a RC-IGBT chip, an anode electrode film and an emitter electrode film are arranged with a distance therebetween. The anode electrode film and the emitter electrode film are electrically connected by a wiring conductor having an external impedance and an external impedance. The external impedance and the external impedance include the resistance of the wiring conductor and the inductance of the wiring conductor.

Semiconductor devices may include a die including a semiconductor material. The die may include a first active surface including first integrated circuitry on a first side of the die and a second active surface including second integrated circuitry on a second, opposite side of the die. In some embodiments, the die may include two die portions: a first die portion including the first active surface and a second die portion including the second active surface. The first die portion and the second die portion may be joined together with the first active surface facing away from the second active surface.

A memory device is disclosed. The disclosed memory device may include a first wafer, and a second wafer stacked on and bonded to the first wafer. The first wafer may include a cell structure including a memory cell array; and a first logic structure disposed under the cell structure, and including a column control circuit. The second wafer may include a second logic structure including a row control circuit.

A high-resolution display device is provided. A display device having both high display quality and high resolution is provided. The display device is provided with a structure that inhibits a reduction in contrast due to the light guided by a layer extending across light-emitting elements. A structure body that absorbs or reflects visible light is provided between adjacent light-emitting elements. This structure body absorbs or reflects the light emitted from a light-emitting element and traveling toward an adjacent pixel, whereby a reduction in contrast due to stray light is inhibited.

A capacitor is made using a wafer, and includes structural elevation portions to allow an electrode layer in the capacitor to be extended along surface profiles of the structural elevation portions to thereby increase its extension length, so as to reduce capacitor area, simplify capacitor manufacturing process and reduce manufacturing cost.

A technique for marking semiconductor devices with an identifiable mark or alphanumeric text yields a high-contrast, easily distinguishable mark on an electrical terminal of the device without impacting the device's breakdown voltage capability and without compromising the solderability and wire bondability of the terminal. This approach deposits the mark on the terminal as a patterned layer of palladium, which offers good contrast with the base metal of the terminal and maintains the solderability and bondability of the terminal.

A method of repairing a display panel and a repaired display panel are provided. The display panel includes a panel substrate, a plurality of micro LEDs arranged on the panel substrate, and a molding member covering the plurality of micro LEDs. The molding member includes a first molding member and a second molding member disposed in a region surrounded by the first molding member. The second molding member has a composition or a shape different from that of the first molding member, and the second molding member surrounds at least one side surface of the plurality of micro LEDs.

A microelectronic device, in a fan-out fan-in chip scale package, has a die and an encapsulation material at least partially surrounding the die. Fan-out connections from the die extend through the encapsulation material and terminate adjacent to the die. The fan-out connections include wire bonds, and are free of photolithographically-defined structures. Fan-in/out traces connect the fan-out connections to bump bond pads. The die and at least a portion of the bump bond pads partially overlap each other. The microelectronic device is formed by mounting the die on a carrier, and forming the fan-out connections, including the wire bonds, without using a photolithographic process. The die and the fan-out connections are covered with an encapsulation material, and the carrier is subsequently removed, exposing the fan-out connections. The fan-in/out traces are formed so as to connect to the exposed portions of the fan-out connections, and extend to the bump bond pads.