A package structure and a manufacturing method thereof are provided. The package structure includes a redistribution layer, a conductive element, an active chip, an encapsulation layer, another redistribution layer, and a conductive terminal. The conductive element, the active chip, and the encapsulation layer are disposed on the redistribution layer and the encapsulation layer surrounds the conductive element and the active chip. The another redistribution layer is disposed on the conductive element, the active chip and the encapsulation layer and electrically connected to the redistribution layer through the conductive element.

A semiconductor device includes: a multilayered wiring layer including an insulation layer (30) and a diffusion prevention layer (21, 22, 23, 24) stacked alternately and including a wiring layer (11, 12, 13) internally; a gap section (50) disposed at least in a portion of the insulation layer (30); and a support section (60) disposed at least in a portion of the gap section (50) and configured to support the multilayered wiring layer.

The present disclosure discloses a method for manufacturing a color Micro LED display chip module, comprising preparing a Micro LED chip on a substrate, grinding and cutting the chip and then flip-bonding same on a driving basal plate, and peeling the substrate from the chip. Through fabricating a quantum dot hole site corresponding to a sub-pixel unit position of a chip on a transparent basal plate and filling a quantum dot light-color converter in the quantum dot hole site and depositing a quantum dot protective layer, a conversion device is fabricated independently on the transparent basal plate. Compared with processing a conversion layer on a substrate layer in the prior art, inverting a full-color quantum dot conversion device and then aligning and bonding same with the integrated monochrome Micro LED module base can improve the fabrication efficiency, eliminate the crosstalk between light and color in full-color Micro LED display.

A chip package structure includes an assembly containing an interposer and semiconductor dies; a packaging substrate attached to the assembly through solder material portions; and a lid structure attached to the packaging substrate. The lid structure includes: a first plate portion having a first thickness and located in an interposer-projection region having an areal overlap with the interposer in a plan view; a second plate portion having a second thickness that is less than the first thickness, laterally surrounding, and adjoined to, the first plate portion, and located outside the interposer-projection region; and a plurality of foot portions adjoined to the second plate portion, laterally spaced from the first plate portion, and attached to a respective top surface segment of the packaging substrate through a respective adhesive portion.

A package structure and method for forming the same are provided. The package structure includes a substrate having a front surface and a back surface, and a die formed on the back surface of the substrate. The package structure includes a first through via structure formed in the substrate, a conductive structure formed in a passivation layer) over the front surface of the substrate. The conductive structure includes a via portion in direct contact with the substrate. The package structure includes a connector (formed over the via portion, wherein the connector includes an extending portion directly on a recessed top surface of the via portion.

A stencil mask and a stencil printing method are provided. The stencil mask includes: a non-reinforcement portion having a mask surface configured to contact a substrate surface of a substrate; and a reinforcement portion having a thickness greater than that of the non-reinforcement portion, wherein the reinforcement portion includes: an embossed surface for insertion into a cavity of the substrate and configured to contact a cavity bottom surface when the stencil mask is placed onto the substrate for stencil printing; and at least one first stencil window that allows the fluid material to flow through the reinforcement portion, wherein the at least one first stencil window is aligned with at least one printing region within the cavity when the stencil mask is placed onto the substrate for stencil printing.

A method of dispensing an underfill material on a semiconductor device package. A substrate having a semiconductor chip electrically connected thereto and offset from the substrate by solder joints is provided. The semiconductor chip has a footprint defined by a length and width of the semiconductor chip. Standoff heights between the substrate and the semiconductor chip are calculated and used to determine a volume of underfill material needed to substantially fill a space between the substrate and the semiconductor chip. The determined volume of underfill material is dispensed on the substrate such that the space between the substrate and the semiconductor chip is substantially filled by the underfill material. The method may allow for improved dispensing an underfill material to substantially fill the space between the substrate and semiconductor chip when variations in standoff height are present.

A semiconductor device semiconductor chip mounted to a leadframe that includes an electrically conductive pad. An electrically conductive clip is arranged in a bridge-like position between the semiconductor chip and the electrically conductive pad. The electrically conductive clip is soldered to the semiconductor chip and to the electrically conductive pad via soldering material applied at coupling surfaces facing towards the semiconductor chip and the electrically conductive pad. The device further includes a pair of complementary positioning formations formed by a cavity in the electrically conductive clip and a protrusion (such as a stud bump or a stack of stud bumps) formed in the electrically conductive pad. The complementary positioning formations are mutually engaged to retain the electrically conductive clip in the bridge-like position to avoid displacement during soldering.

A semiconductor die stack includes a first semiconductor die having a first lattice direction, and a second semiconductor die bonded to the first semiconductor die and having a second lattice direction different than the first lattice direction.

A method for fabricating a package structure is provided. The method includes forming a metal layer over a carrier substrate. The method includes forming a dielectric layer over the metal layer. The method includes forming a plurality of first openings in the dielectric layer. The method includes forming a plurality of second openings in the dielectric layer. The first openings and the second openings expose the metal layer. The method includes forming a conductive material in the first openings and the second openings to form a plurality of conductive features. The method includes removing the metal layer and the carrier substrate. The method includes thinning the dielectric layer around the conductive features. The method also includes bonding a package component to the conductive features.