A bonded assembly includes a first semiconductor die that includes first metallic bonding structures embedded within a first bonding-level dielectric layer, and a second semiconductor die that includes second metallic bonding structures embedded within a second bonding-level dielectric layer and bonded to the first metallic bonding structures by metal-to-metal bonding. One of the first metallic bonding structures a pad portion, and a via portion located between the pad portion and the first semiconductor device, the via portion having second tapered sidewalls.

A light-emitting panel, a method making same, and a display panel are disclosed in the present disclosure. The light-emitting panel includes a light-emitting board which includes a substrate; a first metal layer disposed on the substrate; a gate insulating layer covering the first metal layer; and a second metal layer on a side of the gate insulating layer away from the first metal layer. The second metal layer includes a connection portion located in the bonding area of the light-emitting board, and a conductive protection layer formed by chemical plating is disposed on a surface of the connection portion.

Representative implementations of techniques and methods include processing singulated dies in preparation for bonding. A plurality of semiconductor die components may be singulated from a wafer component, the semiconductor die components each having a substantially planar surface. Particles and shards of material may be removed from edges of the plurality of semiconductor die component. Additionally, one or more of the plurality of semiconductor die components may be bonded to a prepared bonding surface, via the substantially planar surface.

Various embodiments of the present disclosure are directed towards an integrated circuit (IC) chip comprising a semiconductor device that is inverted and that overlies a dielectric region inset into a top of a semiconductor substrate. An interconnect structure overlies the semiconductor substrate and the dielectric region and further comprises an intermetal dielectric (IMD) layer. The IMD layer is bonded to the top of the semiconductor substrate and accommodates a pad. A semiconductor layer overlies the interconnect structure, and the semiconductor device is in the semiconductor layer, between the semiconductor layer and the interconnect structure. The semiconductor device comprises a first source/drain electrode overlying the dielectric region and further overlying and electrically coupled to the pad. The dielectric region reduces substrate capacitance to decrease substrate power loss and may, for example, be a cavity or a dielectric layer. A contact extends through the semiconductor layer to the pad.

A semiconductor structure and a method of manufacturing the semiconductor structure are provided. The semiconductor structure includes a substrate including a plurality of pads spaced apart from each other, a first groove, and a second groove connected with the first groove, the first and the second grooves located in the substrate. The first groove is located on the side of the second groove away from the plurality of pads, and the bottom of the second groove exposes a corresponding pad of the plurality of pads. The orthographic projection of the second groove on the substrate is located within the orthographic projection of the first groove on the substrate. A redistribution layer is disposed on a surface of the corresponding pad, the inner wall of the first groove, and the inner wall and the bottom of the second groove. The semiconductor structure prevents contamination or damage of test probes.

The present disclosure provides a display panel and a display apparatus. The display panel includes a driving back plate, a driving circuit, a first electrode layer, micro-LEDs, a second electrode layer, and a bonding layer. The first electrode layer on the driving circuit is provided with a first protruding structure, and the second electrode layer under the micro-LEDs is provided with a second protruding structure. The bonding layer is disposed between the first electrode layer and the second electrode layer to alleviate the problem of micro-LEDs falling off.

Disclosed is a semiconductor package comprising a semiconductor chip, an external connection member on the semiconductor chip, and a dielectric film between the semiconductor chip and the external connection member. The semiconductor chip includes a substrate, a front-end-of-line structure on the substrate, and a back-end-of-line structure on the front-end-of-line structure. The back-end-of-line structure includes metal layers stacked on the front-end-of-line structure, a first dielectric layer on the uppermost metal layer and including a contact hole that vertically overlaps a pad of an uppermost metal layer, a redistribution line on the first dielectric layer and including a contact part in the contact hole and electrically connected to the pad, a pad part, and a line part that electrically connects the contact part to the pad part, and an upper dielectric layer on the redistribution line.

A package structure includes at least two semiconductor structures that are stacked onto one another. The first surface of one semiconductor structure of the at least two semiconductor structures that are stacked onto one another directly faces toward the second surface of another semiconductor structure of the at least two semiconductor structures which is adjacent to said one semiconductor structure; the first metal layer of said one semiconductor structure is in contact with and bonded to the third metal layer of said another semiconductor structure; and the second metal layer of said one semiconductor structure is in contact with and bonded to the fourth metal layer of said another semiconductor structure.

An integrated circuit chip (die) may include a force mitigation system for reducing or mitigating under-pad stresses typically caused by wire bonding. The IC die may include wire bond pads and a force mitigation system formed below each wire bond pad. The force mitigation system may include a “shock plate” (e.g., metal region), a sealing layer located above the shock plate, and a force mitigation layer including an array of sealed voids between the metal region and the sealing layer. The sealed voids in the force mitigation layer may be defined by forming openings in an oxide dielectric layer and forming a non-conformal sealing layer over the openings to define an array of sealed voids. The force mitigation system may mitigate stresses caused by a wire bond on each wire bond pad, which may reduce or eliminate wire-bond-related damage to semiconductor devices located in the under-pad regions of the die.

An object of the present invention is to provide a circular support substrate that allows for positioning based solely on its outer periphery shape. As a means for solving the problems, a circular support substrate is provided that has at least three chords along its circumference, wherein the chords are provided at positions where they do not run linearly symmetrical to the straight line passing through the center axis of the circular support substrate.