The present disclosure provides a display device. The display device includes a display panel and a bonding object; wherein the display panel is provided with a first bonding pad unit and a plurality of second bonding pad units respectively arranged on two sides of the first bonding pad unit, wherein a height of the first bonding pad unit in a second direction is identical to a height of the second bonding pad unit in the second direction; and the bonding object includes a third bonding pad unit corresponding to the first bonding pad unit, and fourth bonding pad units corresponding to the second bonding pad units, wherein a height of the fourth bonding pad unit in the second direction is less than a height of the third bonding pad unit in the second direction.

A semiconductor device includes a semiconductor substrate, a power transistor formed in the semiconductor substrate, the power transistor including an active area in which one or more power transistor cells are formed, a first metal pad formed above the semiconductor substrate and covering substantially all of the active area of the power transistor, the first metal pad being electrically connected to a source or emitter region in the active area of the power transistor, the first metal pad including an interior region laterally surrounded by a peripheral region, the peripheral region being thicker than the interior region, and a first interconnect plate or a semiconductor die attached to the interior region of the first metal pad by a die attach material. Corresponding methods of manufacture are also described.

In an embodiment, a device includes: a first die array including first integrated circuit dies, orientations of the first integrated circuit dies alternating along rows and columns of the first die array; a first dielectric layer surrounding the first integrated circuit dies, surfaces of the first dielectric layer and the first integrated circuit dies being planar; a second die array including second integrated circuit dies on the first dielectric layer and the first integrated circuit dies, orientations of the second integrated circuit dies alternating along rows and columns of the second die array, front sides of the second integrated circuit dies being bonded to front sides of the first integrated circuit dies by metal-to-metal bonds and by dielectric-to-dielectric bonds; and a second dielectric layer surrounding the second integrated circuit dies, surfaces of the second dielectric layer and the second integrated circuit dies being planar.

A chip package module is provided. The chip package module includes a package substrate, a chip, and a conductive connector assembly. The chip having a first surface and a second surface opposite thereto is disposed on the package substrate. The first surface is divided into a first region, a second region, and a third region, and the second region is located between the first and third regions. The chip includes a flip-chip pad group disposed in the first region, a wire-bonding pad group disposed in the third region, and a signal pad group disposed in the second region. The conductive connector assembly is electrically connected between the chip and the package substrate. One of the flip-chip pad group and the wire-bonding pad group is electrically and physically connected to the conductive connector assembly, and the other one is not physically connected to the conductive connector assembly.

A semiconductor device includes a semiconductor layer that has a principal surface, a first conductive layer that is formed on the principal surface of the semiconductor layer, a first insulating portion that is formed on the principal surface of the semiconductor layer so as to cover the first conductive layer and that includes a first insulating layer of at least three or more layers, a second insulating portion that is formed on the first insulating portion, that has a dielectric constant differing from a dielectric constant of the first insulating layer, and that includes a second insulating layer not included in the first insulating portion, and a second conductive layer that is formed on the second insulating portion, that faces the first conductive layer through the first insulating portion and the second insulating portion, and that is connected to a potential differing from a potential of the first conductive layer.

Representative implementations of techniques and methods include chemical mechanical polishing for hybrid bonding. The disclosed methods include depositing and patterning a dielectric layer on a substrate to form openings in the dielectric layer, depositing a barrier layer over the dielectric layer and within a first portion of the openings, and depositing a conductive structure over the barrier layer and within a second portion of the openings not occupied by the barrier layer, at least a portion of the conductive structure in the second portion of the openings coupled or contacting electrical circuitry within the substrate. Additionally, the conductive structure is polished to reveal portions of the barrier layer deposited over the dielectric layer and not in the second portion of the openings. Further, the barrier layer is polished with a selective polish to reveal a bonding surface on or at the dielectric layer.

A semiconductor structure and a manufacturing method thereof are provided. The semiconductor structure includes an integrated circuit (IC) component, an insulating layer laterally encapsulating sidewalls of the IC component, a redistribution structure disposed on the insulating layer and the IC component, and a warpage control portion coupling to a back side of the IC component opposite to the redistribution structure. The redistribution structure is electrically connected to the IC component. The warpage control portion includes a substrate, a patterned dielectric layer disposed between the substrate and the IC component, and a metal pattern embedded in the patterned dielectric layer and electrically isolated from the IC component.

A solid-state imaging device capable of preventing variation in bonding strength in a bonding plane between a first semiconductor substrate and a second semiconductor substrate is provided. The solid-state imaging device includes a first semiconductor substrate having a plurality of first conductors, and a second semiconductor substrate bonded to the first semiconductor substrate and having a plurality of second conductors. In a bonding plane between the first and second semiconductor substrates, the device includes regions where the conductors overlap, regions where insulating films and the conductors overlap, and regions where the insulating films overlap. The proportion of areas where the first insulating films and the second insulating films are bonded together to the bonding area between the first semiconductor substrate and the second semiconductor substrate is constant before and after the first semiconductor substrate and the second semiconductor substrate are bonded together.

Solid-state lighting devices including light-emitting diodes (LEDs) and more particularly LED chips with interconnect structures are disclosed. LED chips are provided that include first interconnects electrically coupled to an n-type layer and second interconnects electrically connected to a p-type layer. Configurations of the first and second interconnects are provided that may improve current spreading by reducing localized areas of current crowding within LED chips. Various configurations are disclosed that include collectively formed symmetric patterns of the first and second interconnects, diameters of certain ones of either the first or second interconnects that vary based on their relative positions in LED chips, and spacings of the second interconnects that vary based on their distances from the first interconnects. In this regard, LED chips are disclosed with improved current spreading as well as higher lumen outputs and efficiencies.

Solid-state lighting devices including light-emitting diodes (LEDs) and more particularly LED chips with interconnect structures are disclosed. LED chips are provided that include first interconnects electrically coupled to an n-type layer and second interconnects electrically connected to a p-type layer. Configurations of the first and second interconnects are provided that may improve current spreading by reducing localized areas of current crowding within LED chips. Various configurations are disclosed that include collectively formed symmetric patterns of the first and second interconnects, diameters of certain ones of either the first or second interconnects that vary based on their relative positions in LED chips, and spacings of the second interconnects that vary based on their distances from the first interconnects. In this regard, LED chips are disclosed with improved current spreading as well as higher lumen outputs and efficiencies.