A semiconductor device includes a substrate, a conductive section, a sealing resin, and a conductive section wire. The substrate includes a substrate obverse face and a substrate reverse face oriented in opposite directions to each other in a thickness direction. The conductive section is formed of a conductive material and located on the substrate obverse face. The conductive section includes a first section and a second section spaced apart from each other. The sealing resin covers at least a part of the substrate and an entirety of the conductive section. The conductive section wire is conductively bonded to the first section and the second section of the conductive section.

A semiconductor package includes a package substrate having substrate pads disposed in a first direction on one surface, a semiconductor chip having chip pads disposed in the first direction, and bonding wires connecting the chip pads and the substrate pads. The bonding wires include first and second bonding wires alternately connected to the substrate pads respectively, in the first direction, the first bonding wires are connected to the substrate pads at a first angle less than a right angle with respect to a direction of the semiconductor chip, the second bonding wires are connected to the substrate pads at a second angle less than the first angle with respect to the direction of the semiconductor chip and a position at which the first bonding wires contact the substrate pads is closer to the semiconductor chip than a position at which the second bonding wires contact the substrate pads is to the semiconductor chip.

Methods, systems, and devices for polymer material gap-fill for hybrid bonding in a stacked semiconductor system are described. A stacked semiconductor may include a first semiconductor die on a semiconductor wafer. A polymer material may be on the semiconductor wafer and may at least partially surround the first semiconductor die. A silicon nitride material may be on the first semiconductor die and on the polymer material. And a second semiconductor die may be hybrid bonded with a bonding material on the silicon nitride material.

A semiconductor package includes a substrate including a die pad, first and second discrete transistor dies mounted on the die pad, an encapsulant body that encapsulates the first and second discrete transistor dies, and a plurality of leads that are exposed from the encapsulant body, wherein the first and second discrete transistor dies are connected in parallel with one another by electrical interconnections that electrically connect common terminals of the first and second discrete transistor dies to one of the leads, and wherein at least one of the electrical interconnections has a balanced configuration that provides substantially identical electrical impedance as between the common terminals of the first and second discrete transistor dies and the lead to which they are connected.

A semiconductor device includes a substrate having a semiconductor chip mounted thereon, a heat dissipation plate having a front surface on which the substrate is disposed, a case including a side wall disposed on the front surface of the heat dissipation plate so as to surround a housing space accommodating the substrate therein together with the heat dissipation plate and a lid disposed on the side wall to cover the housing space, and a sealing member filling the housing space to seal the substrate. The lid has a through hole and a projection (or a groove) provided on the inner surface of the lid, configured to surround the through hole so as not to contact the sealing member such that the projection forms a plurality of circumferential patterns around the through hole in plan view.

A display device includes a stack portion, a cover glass on the stack portion, a side sealing portion on a side surface of the stack portion, and a coating layer disposed between the stack portion and the side sealing portion. The coating layer includes a hydrophobic material having low surface energy, which reduces adhesion to the side sealing portion and mitigates stress transfer. The stack portion includes a substrate, and an intermediate layer on the substrate, the intermediate layer including a sub intermediate layer and a lower adhesive layer on the sub intermediate layer. By buffering thermal expansion or contraction differences between the stack portion and the side sealing portion, the coating layer helps prevent mechanical stress accumulation that could otherwise result in cracks or delamination. This structure enhances the reliability and durability of the display panel, particularly under thermal cycling, thereby preventing abnormal deformation and improving overall device lifespan.

A method includes removing an oxide layer from select areas of a surface of a metal structure of a lead frame to create openings that extend through the oxide layer to expose portions of the surface of the metal structure. The method further includes attaching a semiconductor die to the lead frame, performing an electrical connection process that electrically couples an exposed portion of the surface of the metal structure to a conductive feature of the semiconductor die, enclosing the semiconductor die in a package structure, and separating the electronic device from the lead frame. In one example, the openings are created by a laser ablation process. In another example, the openings are created by a chemical etch process using a mask. In another example, the openings are created by a plasma process.

A semiconductor device has a substrate and an electrical component disposed over the substrate. An encapsulant is deposited over the electrical component and substrate. A shielding layer has a graphene core shell formed on a surface of the encapsulant. The shielding layer can be printed on the encapsulant. The graphene core shell includes a copper core. The shielding layer has a plurality of cores covered by graphene and the graphene is interconnected within the shielding layer to form an electrical path. The shielding layer also has thermoset material or polymer or composite epoxy type matrix and the graphene core shell is embedded within the matrix. A shielding material can be disposed around the electrical component. The electrical path dissipates any charge incident on shielding layer, such as an ESD event, to reduce or inhibit the effects of EMI, RFI, and other inter-device interference.

A power semiconductor package includes a substrate, a power semiconductor chip arranged on the substrate, and an encapsulant encapsulating the power semiconductor chip. The encapsulant includes a voltage stabilizing additive. The voltage stabilizing additive is configured to minimize or eliminate partial discharges within the encapsulant.

Semiconductor die assemblies with decomposable materials, and associated methods and systems are disclosed. In an embodiment, a semiconductor die assembly includes a memory controller die carrying one or more memory dies attached to its first side. The semiconductor die assembly also includes a biodegradable structure attached to its second side opposite to the first side. The biodegradable structure includes a conductive material and an insulating material, both of which are biodegradable and disintegrate in a wet process. The biodegradable structure can be configured to couple the memory controller die with an interface die. In this manner, when the biodegradable structure disintegrates (e.g., dissolve) in the wet process, the memory controller carrying the memory dies can be separated from the interface die to reclaim the memory controller with the memory dies and the interface die.