A semiconductor package of an embodiment includes: a wiring substrate having a first surface and a second surface on a side opposite to the first surface; at least one semiconductor chip provided in plurality at different heights from the first surface in a vertical direction; a sealing resin covering the first surface of the wiring substrate and surfaces of the at least one semiconductor chip; a layer formed over a top layer of the at least one semiconductor chip; and an external terminal provided on the second surface of the wiring substrate. The wiring substrate is electrically connectable with a printed wiring board through the external terminal.

There is provided a semiconductor memory device that has improved performance and/or reliability. The semiconductor memory device includes a substrate, a stacked structure including a plurality of gate electrodes stacked on the substrate and spaced apart from each other in a first direction, the first direction being perpendicular to an upper surface of the substrate, a channel structure extending in the first direction and crossing the plurality of gate electrodes, and a dam structure extending in the first direction and surrounding at least a portion of the stacked structure in a plan view, on the substrate. A height of an upper surface of the dam structure from the upper surface of the substrate is lower than a height of the channel structure from the upper surface of the substrate.

A semiconductor package includes a connection substrate on a package substrate and has an opening that penetrates therethrough. A chip stack is on the package substrate and in the opening. A redistribution layer is on the connection substrate and the chip stack. An upper semiconductor chip is on first redistribution pads of the redistribution layer. External terminals are on a bottom surface of the package substrate. The chip stack includes a first semiconductor chip on substrate pads of the package substrate, and a second semiconductor chip on the first semiconductor chip and second redistribution pads of the redistribution layer. The redistribution layer includes a first region that overlaps the upper semiconductor chip and a second region beside the upper semiconductor chip. The first redistribution pads are on the first region. The second redistribution pads are on the second region.

A display module includes: a substrate having a mounting surface, four side surfaces, and a rear surface opposite to the mounting surface, the substrate including a thin film transistor layer (TFT) provided on the mounting surface; a plurality of inorganic light-emitting diodes provided on the mounting surface of the substrate; a side wiring electrically connected to the TFT layer and extending along a first pair of side surfaces among the four side surfaces of the substrate; a front cover covering the TFT layer and the plurality of inorganic light emitting devices in a first direction; a metal plate provided on the rear surface of the substrate; a side cover covering the side wiring and the four side surfaces; and a side member provided on a side of the side cover and grounded to the metal plate, wherein the side member is provided on a first side surface of the first pair of side surfaces along which the side wiring extends among the four side surfaces.

A semiconductor chip includes: a photonic integrated circuit (PIC) comprising an active component electrically connected to a first landing pad at a surface of the PIC, wherein the first landing pad is configured to receive a copper pillar, which, when installed, provides at least a portion of a first electrical interconnect between the active photonic component and a second integrated circuit to be stacked on the surface of the PIC, and wherein, when viewed from above the PIC towards the PIC, a center of the active photonic component on the PIC is offset from a nearest edge of the first landing pad by about a distance less than 10 m.

A display device is provided and includes: a plurality of display modules disposed on the first bearing surface, each of the display modules including a plurality of display units; a plurality of first functional elements located on the first bearing surface, and each of the first functional elements disposed between any two of the display units; and a plurality of second functional elements located on the second bearing surface; wherein a function of each of the second functional elements is the same as a function of each of the first functional elements, and processing capability of each of the second functional elements is different from processing capability of each of the first functional elements.

The package-on-package (POP) structure includes a first package unit of three-dimensional fan-out memory chips and a SiP package unit of the two-dimensional fan-out peripheral circuit chip. The first package unit includes: memory chips laminated in a stepped configuration; a molded substrate; wire bonding structures; a first rewiring layer; a first encapsulating layer; and first metal bumps, formed on the first rewiring layer. The SiP package unit includes: a second rewiring layer; a peripheral circuit chip; a third rewiring layer, bonded to the circuit chip; first metal connection pillars; a second encapsulating layer for the circuit chip and the first metal connection pillars; and second metal bumps on the second rewiring layer. The first metal bumps are bonded to the third rewiring layer. Integrating the two package units into the POP is enabled by three rewiring layers and the molded substrate which supports the first package unit during wire bonding process.

A semiconductor package includes; a redistribution wiring layer, a controller chip centrally disposed on the redistribution wiring layer, a first sealant disposed on the redistribution wiring layer, wherein the controller chip is buried in the first sealant, through vias connected to the redistribution wiring layer through the first sealant, and a sub-package disposed on an upper surface of the first sealant. The sub-package may include a first stack structure disposed to one side of the controller chip on the upper surface of the first sealant and including vertically stacked chips, a second stack structure disposed to another side of the controller chip on the upper surface of the first sealant adjacent to the first stack structure in a first horizontal direction and including vertically stacked chips, and a second sealant sealing the first stack structure and the second stack structure.

A semiconductor device package and a method of manufacturing a semiconductor device package are provided. The semiconductor device package includes a carrier, a first component, a second component, and a protective element. The first component and the second component are arranged side by side in a first direction over the carrier. The protective element is disposed over a top surface of the carrier and extending from space under the first component toward a space under the second component. The protective element includes a first portion and a second portion protruded oppositely from edges of the first component by different distances, and the first portion and the second portion are arranged in a second direction angled with the first direction.

A semiconductor package includes: a base chip; semiconductor chips disposed on the base chip and including front pads disposed on a front surface opposing the base chip, rear pads disposed on a rear surface opposing the front surface, and through-vias; bumps disposed between the semiconductor chips; a dam structure disposed on at least a portion of the rear pads; and insulating adhesive layers at least partially surrounding the bumps and the dam structure, wherein the rear pads include first pads that are disposed in a center region that crosses a center of the rear surface and that are electrically connected to the through-vias, and second pads that are disposed in a peripheral region adjacent to the center region, wherein the second pads include a line pad of which at least a portion has a polygonal shape, and wherein the dam structure has a bent shape.