Implementations described herein relate to various semiconductor device assemblies. In some implementations, a semiconductor device assembly includes a substrate, a first integrated circuit die over the substrate including a first recess that penetrates into a first edge of the first integrated circuit die, and a second integrated circuit die over the first integrated circuit die including a second recess that penetrates into a second edge of the second integrated circuit die. The semiconductor device assembly includes a pillar structure that uses the first recess and the second recess to align perimeters of the first integrated circuit die and the second integrated circuit die.

A semiconductor package comprises a first die having a central region and a peripheral region that surrounds the central region; a plurality of through electrodes that penetrate the first die; a plurality of first pads at a top surface of the first die and coupled to the through electrodes; a second die on the first die; a plurality of second pads at a bottom surface of the second die, the bottom surface of the second die facing the top surface of the first die; a plurality of connection terminals that connect the first pads to the second pads; and a dielectric layer that fills a space between the first die and the second die and surrounds the connection terminals. A first width of each of the first pads in the central region may be greater than a second width of each of the first pads in the peripheral region.

Provided is a chip stack structure including a passivation layer, a plurality of conductive pillars passing through the passivation layer, a buffer chip located on the passivation layer, a plurality of core chips located on the buffer chip and stacked in a vertical direction, and a first molding layer located on the passivation layer and surrounding the buffer chip and the plurality of core chips, wherein an area of an upper surface of the passivation layer is greater than an area of a lower surface of the buffer chip.

A semiconductor package includes a redistribution layer including, a first insulating layer including a first trench, a first conductive layer including a first conductive region extending along a top surface of the first insulating layer and a second conductive region disposed inside the first trench, a second insulating layer on the first conductive layer and the first insulating layer, the second insulating layer including a second trench at least partially overlapping the first trench, the second trench exposing a part of the first conductive region and a second conductive layer including a third conductive region extending along a top surface of the second insulating layer and a fourth conductive region disposed on the second conductive region inside a via trench including sidewalls of the first trench and the second trench, and wherein the second and fourth conductive regions have a width in a range of 20 m to 600 m.

A method of electroplating a metal into features, having substantially different depths, of a partially fabricated electronic device on a substrate is provided. The method includes adsorbing accelerator into the bottom of recessed features; partially filling the features by a bottom up fill mechanism in an electroplating solution; diffusing leveler into shallow features to decrease the plating rate in shallow features as compared to deep features; and electroplating more metal into the features such that the height of metal in deep features is similar to the height of metal in shallow features.

A vertical solid state device comprising: a connection pad; and side walls comprising a metal-insulator-semiconductor (MIS) structure; wherein a gate of the MIS structure is shorted to at least one contact of the vertical solid state device and a threshold voltage (VT) of the MIS structure is adjusted to increase the efficiency of the device.

A package structure is provided. The package structure includes a dielectric structure and an antenna structure disposed in the dielectric structure. The package structure also includes a semiconductor device disposed on the dielectric structure and a protective layer surrounding the semiconductor device. The package structure further includes a conductive feature electrically connecting the semiconductor device and the antenna structure. A portion of the antenna structure is between the conductive feature and the dielectric structure.

An electronic device, includes: (i) a processing chiplet configured to process data and having a first side and a second side, (ii) one or more first static random-access memory (SRAM) chiplets disposed on the first side of the processing chiplet and configured to store a first portion of the data, (iii) one or more second SRAM chiplets disposed on the second side of the processing chiplet and configured to store a second portion of the data, (iv) one or more first electrical terminals disposed on the first side of the processing chiplet and configured to electrically connect between the first side of the processing chiplet and the first SRAM chiplets, and (v) one or more second electrical terminals disposed on the second side of the processing chiplet and configured to electrically connect between the second side of the processing chiplet and the second SRAM chiplets.

A method is described. The method includes creating a partial through-substrate via (TSV) plug in a front side of a wafer, the partial TSV having a front side and a back side. The back side of the partial TSV extending toward a front side of a substrate but not into a bulk of the substrate. A cavity is etched in a back side of the wafer that exposes the partial TSV plug. An insulator is applied to the etched back side of the wafer. A portion of the partial TSV plug is exposed by removing a portion of the insulator. A conductive material is deposited to connect the exposed, partial TSV plug to a surface on the back side of the wafer.

Techniques for signal routing between a host and dynamic random-access memory (DRAM) are provided. In an example, a routing layer for a dynamic random-access memory die (DRAM can include multiple through silicon via (TSV) terminations configured to electrically couple with TSVs of the DRAM, an intermediate interface area, and multiple routing traces. the multiple TSV terminations can be arranged in multiple TSV areas. The multiple TSV areas can be arranged in two columns. The intermediate interface area can include multiple micro-pillar bump terminations configured to couple, via a micro-pillar bump, with corresponding micro-pillar bump terminations of a semiconductor interposer. The multiple routing traces can couple control TSV terminations of the multiple TSV areas with a corresponding micro-pillar bump termination of the intermediate interface.