A multi-chip package comprising an interconnection substrate; a first semiconductor IC chip over the interconnection substrate, wherein the first semiconductor IC chip comprises a first silicon substrate, a plurality of first metal vias passing through the first silicon substrate, a plurality of first transistors on a top surface of the first silicon substrate and a first interconnection scheme over the first silicon substrate, wherein the first interconnection scheme comprises a first interconnection metal layer over the first silicon substrate, a second interconnection metal layer over the first interconnection layer and the first silicon substrate and a first insulating dielectric layer over the first silicon substrate and between the first and second interconnection metal layers; a second semiconductor IC chip over and bonded to the first semiconductor IC chip; and a plurality of second metal vias over and coupling to the interconnection substrate, wherein the plurality of second metal vias are in a space extending from a sidewall of the first semiconductor IC chip.

Various embodiments of the present application are directed towards a semiconductor packaging device including a shield structure configured to block magnetic and/or electric fields from a first electronic component and a second electronic component. The first and second electronic components may, for example, be inductors or some other suitable electronic components. In some embodiments, a first IC chip overlies a second IC chip. The first IC chip includes a first substrate and a first interconnect structure overlying the first substrate. The second IC chip includes a second substrate and a second interconnect structure overlying the second substrate. The first and second electronic components are respectively in the first and second interconnect structures. The shield structure is directly between the first and second electronic components. Further, the shield structure substantially covers the second electronic component and/or would substantially cover the first electronic component if the semiconductor packaging device was flipped vertically.

A package structure includes a base material, at least one electronic device, at least one encapsulant and a plurality of dummy pillars. The electronic device is electrically connected to the base material. The encapsulant covers the electronic device. The dummy pillars are embedded in the encapsulant. At least two of the dummy pillars have different heights.

In some embodiments, the present disclosure relates to method of forming an integrated circuit, including forming a semiconductor device on a frontside of a semiconductor substrate; depositing a dielectric layer over a backside of the semiconductor substrate; patterning the dielectric layer to form a first opening in the dielectric layer so that the first opening exposes a surface of the backside of the semiconductor substrate; depositing a glue layer having a first thickness over the first opening; filling the first opening with a first material to form a backside contact that is separated from the semiconductor substrate by the glue layer; and depositing more dielectric layers, bonding contacts, and bonding wire layers over the dielectric layer to form a second bonding structure on the backside of the semiconductor substrate, so that the backside contact is coupled to the bonding contacts and the bonding wire layers.

A composite integrated circuit (IC) device structure comprising a host chip and a chiplet. The host chip comprises a first device layer and a first metallization layer. The chiplet comprises a second device layer and a second metallization layer that is interconnected to transistors of the second device layer. A top metallization layer comprising a plurality of first level interconnect (FLI) interfaces is over the chiplet and host chip. The chiplet is embedded between a first region of the first device layer and the top metallization layer. The first region of the first device layer is interconnected to the top metallization layer by one or more conductive vias extending through the second device layer or adjacent to an edge sidewall of the chiplet.

Provided is a semiconductor architecture including a carrier substrate, alignment marks provided in the carrier substrate, the alignment marks being provided from a first surface of the carrier substrate to a second surface of the carrier substrate, a first semiconductor device provided on the first surface of the carrier substrate based on the alignment marks, a second semiconductor device provided on the second surface of the carrier substrate based on the alignment marks and aligned with the first semiconductor device.

A semiconductor package is provided. The semiconductor package may include a first semiconductor die, a second semiconductor die stacked on the first semiconductor die, the second semiconductor die having a width smaller than a width of the first semiconductor die, a third semiconductor die stacked on the second semiconductor die, the third semiconductor die having a width smaller than the width of the first semiconductor die, and a mold layer covering side surfaces of the second and third semiconductor dies and a top surface of the first semiconductor die. The second semiconductor die may include a second through via, and the third semiconductor die may include a third conductive pad in contact with the second through via.

A method includes forming a plurality of low-k dielectric layers over a semiconductor substrate, forming a first plurality of dummy stacked structures extending into at least one of the plurality of low-k dielectric layers, forming a plurality of non-low-k dielectric layers over the plurality of low-k dielectric layers, and forming a second plurality of dummy stacked structures extending into the plurality of non-low-k dielectric layers. The second plurality of dummy stacked structures are over and connected to corresponding ones of the first plurality of dummy stacked structures. The method further includes etching the plurality of non-low-k dielectric layers, the plurality of low-k dielectric layers, and the semiconductor substrate to form a via opening. The via opening is encircled by the first plurality of dummy stacked structures and the second plurality of dummy stacked structures. The via opening is then filled to form a through-via.

The present disclosure provides a method of manufacturing a semiconductor device and a semiconductor device. The method of manufacturing a semiconductor device includes: providing a substrate with trenches, and the trenches extending along a thickness direction of the substrate from a first surface of the substrate; forming a first auxiliary layer and a first conductive layer successively in the trenches, and the first conductive layer covering the first auxiliary layer; thinning the substrate on a second surface of the substrate to expose the first auxiliary layer; removing the first auxiliary layer to form first openings; forming a second medium layer on the second surface of the substrate; patterning the second medium layer to form second openings in the second medium layer, and the second openings exposing the first openings; and depositing a second initial conductive layer, the second initial conductive layer filling the first openings and the second openings.

A three-dimensional (3D) memory device includes a first semiconductor structure and a second semiconductor structure. A first semiconductor structure includes a first substrate, and a memory array structure disposed on the first substrate. The second semiconductor structure is disposed over the first semiconductor structure, and the second semiconductor structure includes a second substrate, and a peripheral device in contact with the second substrate. The second substrate is formed between the peripheral device and the first semiconductor structure.