A display module and a method for manufacturing thereof are provided. The display module includes a glass substrate; a thin film transistor (TFT) layer provided on a surface of the glass substrate, the TFT layer including a plurality of TFT electrode pads; a plurality of light emitting diodes (LEDs) provided on the TFT layer, each of the plurality of LEDs including LED electrode pads that are electrically connected to respective TFT electrode pads among the plurality of TFT electrode pads; and a light shielding member provided on the TFT layer and between the plurality of LEDs, wherein a height of the light shielding member with respect to the TFT layer is lower than a height of the plurality of LEDs with respect to the TFT layer.

Provided is a package structure including a composite wafer, a plurality of dies, an underfill, and a plurality of dam structures. The composite wafer has a first surface and a second surface opposite to each other. The composite wafer includes a plurality of seal rings dividing the composite wafer into a plurality of packages; and a plurality of through holes respectively disposed between the seal rings and penetrating through the first and second surfaces. The dies are respectively bonded onto the packages at the first surface by a plurality of connectors. The underfill laterally encapsulates the connectors. The dam structures are disposed on the first surface of the composite wafer to separate the underfill from the through holes.

A semiconductor device package includes a semiconductor device, a non-semiconductor substrate over the semiconductor device, and a first connection element extending from the semiconductor device to the non-semiconductor substrate and electrically connecting the semiconductor device to the non-semiconductor substrate.

A package includes a first die, a second die, a semiconductor frame, and a reinforcement structure. The first di has a first surface and a second surface opposite to the first surface. The first die includes grooves on the first surface. The second die and the semiconductor frame are disposed side by side over the first surface of the first die. The semiconductor frame has at least one notch exposing the grooves of the first die. The reinforcement structure is disposed on the second surface of the first die. The reinforcement structure includes a first portion aligned with the grooves.

A semiconductor device and method is disclosed. The semiconductor device may include a semiconductor substrate including an active area, a metal layer structure over the active area, wherein the metal layer structure is configured to form an electrical contact, the metal layer structure including a solder area, a buffer area, and a barrier area between the solder area and the buffer area, wherein, in the barrier area, the metal layer structure is further away from the active area than in the solder area and in the buffer area, and wherein each of the solder area and the buffer area is in direct contact with the active area or with a wiring layer structure arranged between the active area and the metal layer structure.

A method for forming a chip package structure is provided. The method includes disposing a chip package over a wiring substrate. The method includes forming a first heat conductive structure and a second heat conductive structure over the chip package. The first heat conductive structure and the second heat conductive structure are separated by a first gap. The method includes bonding a heat dissipation lid to the chip package through the first heat conductive structure and the second heat conductive structure. The first heat conductive structure and the second heat conductive structure extend toward each other until the first heat conductive structure contacts the second heat conductive structure during bonding the heat dissipation lid to the chip package.

Disclosed herein are structures and techniques for underfill flow management in electronic assemblies. For example, in some embodiments, an electronic assembly may include a first component, a second component, an underfill on the first component and at least partially between the first component and the second component, and a material at a surface of the first component, wherein the material is outside a footprint of the second component, and the underfill contacts the material with a contact angle greater than 50 degrees.

Various embodiments provide a semiconductor chip, wherein the semiconductor chip comprises a first contact area and a second contact area both formed at a frontside of the semiconductor chip; a passivation layer arranged at the frontside between the first contact area and the second contact area; and a contact stack formed over the frontside of the semiconductor chip and comprising a plurality of layers, wherein at least one layer of the plurality of layers is removed from the passivation layer and boundary regions of the contact areas being adjacent to the passivation layer and wherein at least one another layer of the plurality of different layer is present in the boundary region of the contact areas adjoining the passivation layer.

A semiconductor apparatus includes an interconnect substrate having a first major surface, a first semiconductor device having a second major surface and mounted to the interconnect substrate, the second major surface opposing the first major surface, a second semiconductor device having a third major surface and a fourth major surface and mounted to the first semiconductor device, the third major surface opposing the first major surface, the fourth major surface opposing the second major surface, a through hole formed through the interconnect substrate at a position overlapping the second semiconductor device in a plan view taken in a thickness direction of the interconnect substrate, and a heatsink member disposed in contact with part of the third major surface, at least a part of the first major surface, and at least a part of a sidewall surface of the through hole.

A semiconductor apparatus includes an interconnect substrate having a first major surface, a first semiconductor device having a second major surface and mounted to the interconnect substrate, the second major surface opposing the first major surface, a second semiconductor device having a third major surface and a fourth major surface and mounted to the first semiconductor device, the third major surface opposing the first major surface, the fourth major surface opposing the second major surface, a through hole formed through the interconnect substrate at a position overlapping the second semiconductor device in a plan view taken in a thickness direction of the interconnect substrate, and a heatsink member disposed in contact with part of the third major surface, at least a part of the first major surface, and at least a part of a sidewall surface of the through hole.