Semiconductor packages with pass-through clock traces and associated devices, systems, and methods are disclosed herein. In one embodiment, a semiconductor device includes a package substrate including a first surface having a plurality of substrate contacts, a first semiconductor die having a lower surface attached to the first surface of the package substrate, and a second semiconductor die stacked on top of the first semiconductor die. The first semiconductor die includes an upper surface including a first conductive contact, and the second semiconductor die includes a second conductive contact. A first electrical connector electrically couples a first one of the plurality of substrate contacts to the first and second conductive contacts, and a second electrical connector electrically couples a second one of the plurality of substrate contacts to the first and second conductive contacts.

A wafer-level chip structure, a multiple-chip stacked and interconnected structure and a fabricating method thereof, wherein the wafer-level chip structure includes: a through-silicon via, which penetrates a wafer; a first surface including an active region, a multi-layered redistribution layer and a bump; and a second surface including an insulation dielectric layer, and a frustum transition structure connected with the through-silicon via. In an embodiment of the present application, a frustum type impedance transition structure is introduced into a position between a TSV exposed area on a backside of a wafer and a UBM so as to implement an impedance matching between TSV and UBM, thereby alleviating the problem of signal distortion that is caused by an abrupt change of impedance.

Embodiments of the invention include molded modules and methods for forming molded modules. According to an embodiment the molded modules may be integrated into an electrical package. Electrical packages according to embodiments of the invention may include a die with a redistribution layer formed on at least one surface. The molded module may be mounted to the die. According to an embodiment, the molded module may include a mold layer and a plurality of components encapsulated within the mold layer. Terminals from each of the components may be substantially coplanar with a surface of the mold layer in order to allow the terminals to be electrically coupled to the redistribution layer on the die. Additional embodiments of the invention may include one or more through mold vias formed in the mold layer to provide power delivery and/or one or more faraday cages around components.

Embodiments of the invention include molded modules and methods for forming molded modules. According to an embodiment the molded modules may be integrated into an electrical package. Electrical packages according to embodiments of the invention may include a die with a redistribution layer formed on at least one surface. The molded module may be mounted to the die. According to an embodiment, the molded module may include a mold layer and a plurality of components encapsulated within the mold layer. Terminals from each of the components may be substantially coplanar with a surface of the mold layer in order to allow the terminals to be electrically coupled to the redistribution layer on the die. Additional embodiments of the invention may include one or more through mold vias formed in the mold layer to provide power delivery and/or one or more faraday cages around components.

Methods, systems, and devices for power distribution for stacked memory are described. A memory die may be configured with one or more conductive paths for providing power to another memory die, where each conductive path may pass through the memory die but may be electrically isolated from circuitry for operating the memory die. Each conductive path may provide an electronic coupling between at least one of a first set of contacts of the memory die (e.g., couplable with a power source) and at least one of a second set of contacts of the memory die (e.g., couplable with another memory die). To support operations of the memory die, a contact of the first set may be coupled with circuitry for operating a memory array of the memory die, and to support operations of another memory die, another contact of the first set may be electrically isolated from the circuitry.

Integrated circuit (IC) packages with On Package Memory (OPM) architectures are disclosed herein. An example IC package includes a substrate having a first side and a second side opposite the first side, a semiconductor die mounted on the first side of the substrate, and a die pad on the first side of the substrate. The die is electrically coupled to the die pad. The IC package also includes a memory pad on the first side of the substrate. The memory pad is to be electrically coupled to a memory mounted on the first side of the substrate. The IC package further includes a ball on the second side of the substrate, and a memory interconnect in the substrate electrically coupling the die pad, the memory pad, and the ball.

A semiconductor package includes a substrate extending in a first direction and a second direction perpendicular to the first direction, a first semiconductor chip disposed on the substrate, the first semiconductor chip having a stepped portion, a second semiconductor chip disposed on the substrate and horizontally spaced apart from the first semiconductor chip in the first direction, a third semiconductor chip disposed on the second semiconductor chip and a bottom surface of the stepped portion, and an upper adhesive layer disposed between the second semiconductor chip and the third semiconductor chip, the upper adhesive layer contacting a portion of the bottom surface of the stepped portion.

A semiconductor package includes a base redistribution layer, a first semiconductor chip on the base redistribution layer, at least two chip stacks stacked on the first semiconductor chip and each including a plurality of second semiconductor chips, a first molding layer covering an upper surface of the first semiconductor chip and surrounding the at least two chip stacks, a third semiconductor chip between the base redistribution layer and the first semiconductor chip, a plurality of connection posts between the base redistribution layer and the first semiconductor chips paced apart from the third semiconductor chip in a horizontal direction, and a second molding layer surrounding the third semiconductor chip and the plurality of connection posts between the base redistribution layer and the first semiconductor chip.

A device is provided. The device includes a bridge layer over a first substrate. A first connector electrically connecting the bridge layer to the first substrate. A first die is coupled to the bridge layer and the first substrate, and a second die is coupled to the bridge layer.

Provided is a semiconductor package including a redistribution structure including at least one redistribution insulating layer and at least one redistribution pattern, at least one semiconductor chip located on the redistribution structure, and a molding layer located on the redistribution structure and covering the at least one semiconductor chip. The redistribution pattern includes a redistribution via passing through the redistribution insulating layer and extending in a first direction perpendicular to a top surface of the redistribution structure, and a redistribution line extending in a second direction parallel to the top surface of the redistribution structure. Inner side walls of the redistribution via have a certain inclination, and a difference between a thickness of a central portion of the redistribution line and a thickness of an edge of the redistribution line ranges from 1% to 10% of the thickness of the central portion of the redistribution line.