The present disclosure relates an integrated chip structure. The integrated chip structure includes a first chiplet predominantly having a first plurality of integrated chip devices coupled to a first plurality of interconnects over a first substrate. The first plurality of integrated chip devices are a first type of integrated chip device. The integrated chip structure further includes a second chiplet predominantly having a second plurality of integrated chip devices coupled to a second plurality of interconnects over a second substrate. The second plurality of integrated chip devices are a second type of integrated chip device different than the first type of integrated chip device. One or more inter-chiplet connectors are between the first and second chiplets and are configured to electrically couple the first and second chiplets. The first plurality of interconnects have a first minimum width different than a second minimum width of the second plurality of interconnects.

A bonding structure is provided, including a first substrate; a second substrate disposed opposite the first substrate; a first bonding layer disposed on the first substrate; a second bonding layer disposed on the second substrate and opposite the first bonding layer; and a silver feature disposed between the first bonding layer and the second bonding layer. The silver feature includes a silver nano-twinned structure including parallel twin boundaries. The silver nano-twinned structure includes 90% or more [111] crystal orientation. A method for forming a bonding structure is also provided. Each of steps of forming a first silver feature and second silver feature includes sputtering or evaporation coating. Negative bias ion bombardment is applied to the first silver feature and second silver feature during sputtering or evaporation.

One or more die stacks are disposed on a redistribution layer (RDL) to make an electronic package. The die stacks include a die and one or more Through Silicon Via (TSV) dies. Other components and/or layers, e.g. interposes layers, can be included in the structure. An epoxy layer disposed on the RDL top surface and surrounds and attached to all the TSV die sides and all the die sides. Testing circuitry is located in various locations in some embodiments. Locations including in the handler, die, TSV dies, interposes, etc. Testing methods are disclosed, Methods of making including “die first” and “die last” methods are also disclosed. Methods of making heterogenous integrated structure and the resulting structures are also disclosed, particularly for large scale, e.g. wafer and panel size, applications.

A semiconductor device assembly includes a first remote distribution layer (RDL), the first RDL comprising a lower outermost planar surface of the semiconductor device assembly; a first semiconductor die directly coupled to an upper surface of the first RDL by a first plurality of interconnects; a second RDL, the second RDL comprising an upper outermost planar surface of the semiconductor device assembly opposite the lower outermost planar surface; a second semiconductor die directly coupled to a lower surface of the second RDL by a second plurality of interconnects; an encapsulant material disposed between the first RDL and the second RDL and at least partially encapsulating the first and second semiconductor dies; and a third plurality of interconnects extending fully between and directly coupling the upper surface of the first RDL and the lower surface of the second RDL.

The present application discloses a semiconductor chip, a semiconductor device and an electrostatic discharge (ESD) protection method for a semiconductor device. The semiconductor chip includes an electrical contact, an application circuit, and an ESD protection unit. The application circuit performs operations according to a one signal received by the electrical contact. The ESD protection unit is coupled to the electrical contact. The capacitance of the ESD protection unit is adjustable.

A display is provided. The display includes a first substrate comprising a plurality of electrode pads disposed on a front surface, a plurality of solder members disposed on a rear surface, and a plurality of wiring members electrically connecting the plurality of electrode pads and the plurality of solder members, respectively, a plurality of light-emitting elements electrically connected to each of the plurality of electrode pads, and constituting pixels of two columns, and a second substrate comprising a thin film transistor (TFT) layer disposed on a rear side of the first substrate and electrically connected to the plurality of solder members to control driving of the plurality of light-emitting elements, and the first substrate may include a first region in which pixels of a first column are disposed, a second region in which pixels of a second column are disposed, and a third region disposed between the first region and the second region, the plurality of wiring members may be disposed on the first region and the second region among the front surface of the first substrate.

A semiconductor package including a first substrate including a first bump pad and a filling compensation film (FCF) around the first bump pad; a second substrate facing the first substrate and including a second bump pad; a bump structure (BS) in contact with the first bump pad and the second bump pad; and a non-conductive film (NCF) surrounding the BS and between the first substrate and the second substrate, wherein the NCF covers an upper surface and an edge of the FCF.

Stacked semiconductor die assemblies having memory dies stacked between partitioned logic dies and associated systems and methods are disclosed herein. In one embodiment, a semiconductor die assembly can include a first logic die, a second logic die, and a thermally conductive casing defining an enclosure. The stack of memory dies can be disposed within the enclosure and between the first and second logic dies.

A semiconductor device including a first structure including a first conductive pattern, the first conductive pattern exposed on an upper portion of the first structure, a mold layer covering the first conductive pattern, a second structure on the mold layer, and a through via penetrating the second structure and the mold layer, the through via electrically connected to the first conductive pattern, the through via including a first via segment in the second structure and a second via segment in the mold layer, the second via segment connected to the first via segment, an upper portion of the second via segment having a first width and a middle portion of the second via segment having a second width greater than the first width may be provided.

Disclosed embodiments include frame-array interconnects that have a ledge portion to accommodate a passive device. A seated passive device is between at least two frame-array interconnects for semiconductor package-integrated decoupling capacitors.