The present disclosure relates to an integrated chip including a dielectric structure over a substrate. A first capacitor is disposed between sidewalls of the dielectric structure. The first capacitor includes a first electrode between the sidewalls of the dielectric structure and a second electrode between the sidewalls and over the first electrode. A second capacitor is disposed between the sidewalls. The second capacitor includes the second electrode and a third electrode between the sidewalls and over the second electrode. A third capacitor is disposed between the sidewalls. The third capacitor includes the third electrode and a fourth electrode between the sidewalls and over the third electrode. The first capacitor, the second capacitor, and the third capacitor are coupled in parallel by a first contact on a first side of the first capacitor and a second contact on a second side of the first capacitor.

A method for manufacturing a semiconductor device includes forming a trench on a first main surface of a conductive semiconductor substrate. The method includes laminating conductive layers, each of which is a first or a second conductive layer, along a surface normal direction of a side surface of the trench, while forming dielectric layers between a conductive layer closest to the side surface of the trench and the side surface of the trench, and between the corresponding conductive layers; and removing the first conductive layer and the dielectric layer, which are formed on a bottom portion of the trench, to electrically connect the second conductive layer to the semiconductor substrate at the bottom portion of the trench. After a portion of the first main surface, the portion being outside of the trench, is covered with an insulating protective film, the first conductive layer and the dielectric layer are removed.

The present disclosure relates to a process to integrate sintered components in a laminate substrate. The disclosed process starts with providing a precursor substrate, which includes a substrate body having an opening through the substrate body, and a first foil layer. Herein, the first foil layer is formed underneath the substrate body, so as to fully cover a bottom of the opening. Next, a sinterable base material is applied into the opening and over the first foil layer, and then sintered at a first sintering temperature to create a sintered base component. A sinterable contact material is applied over the sintered base component, and then sintered at a second sintering temperature to create a sintered contact film. The sintered base component is confined within the opening by the substrate body on sides, by the first foil layer on bottom, and by the sintered contact film on top.

Some implementations described herein provide a semiconductor device and methods of formation. The semiconductor device may include a photodiode device electrically connected to a metal-insulator-metal deep-trench capacitor. The metal-insulator-metal deep-trench capacitor includes a layer of an amorphous material between an insulator layer stack of the deep-trench capacitor structure and a capacitor bottom metal layer of the metal-insulator-metal deep-trench capacitor. The amorphous material includes a bandgap energy level that provides a conduction band offset and lowers a probability of electron tunneling from the capacitor bottom metal electrode layer to the insulator layer stack. In this way, leakage associated with grain boundaries, crystal defects, and interfaces of a bottom layer of the insulator layer stack may be overcome to improve a lag performance of the semiconductor device including the metal-insulator-metal deep-trench capacitor.

A semiconductor structure with an MIM capacitor includes a first transistor. The first transistor includes a source and a drain. An interlayer dielectric layer covers the first transistor. A source plug penetrates the interlayer dielectric layer and contacts the source. A drain plug penetrates the interlayer dielectric layer and contacts the drain. A metal interlayer dielectric layer covers the interlayer dielectric layer. An MIM capacitor is disposed in the interlayer dielectric layer and the metal interlayer dielectric layer.

Described examples include an integrated circuit including a dielectric layer located over a top surface of a semiconductor substrate and extending over a gate electrode. A trench extends from a top surface of the dielectric layer into the substrate. A conductive trench electrode is within the trench, and a dielectric liner is between the trench electrode and the semiconductor substrate. A cap dielectric layer is located on the conductive trench electrode and on the dielectric layer, and extends over the gate electrode.

Technologies for components embedded in a substrate core are disclosed. In one embodiment, power components such as deep trench capacitors are disposed in a cavity defined in a substrate core for a circuit board of an integrated circuit package, such as a processor. The power components are stacked on top of each other, allowing for the stack of power components to match the height of the substrate core, even when the height of the individual power components is less than the height of the substrate core. Configuring the power components in this manner can provide mechanical stability to the power components and substrate core and provide power to a semiconductor die mounted on the circuit board.

In some embodiments, the present disclosure relates to an integrated circuit (IC), including a first insulating layer which includes a first metal interconnect structure stacked above a bottom die. Including a substrate disposed above the first insulating layer, a second metal interconnect structure disposed above the substrate, a through-substrate via (TSV) directly connecting the first metal interconnect structure to the second metal interconnect structure, and a stacked deep trench capacitor (DTC) structure disposed in the substrate. The DTC structure includes a first plurality of trenches extending from a first side of the substrate and a second plurality of trenches extending from a second side of the substrate.

The invention provides a semiconductor structure with a deep trench capacitor structures, which comprises a substrate, the substrate comprises a bottle-shaped trench, wherein the bottle-shaped trench has an upper part and a lower part in a cross section, and the interface between the upper part and the lower part is a bottleneck line, wherein the bottleneck line is the part with the smallest width in the bottle-shaped trench, a first dielectric layer is filled in the bottle-shaped trench, and a void is located in the first dielectric layer, wherein the highest point of the void is lower than the bottleneck line.

A capacitor structure and method of forming the capacitor structure is provided, including a providing a doped region of a substrate having a two-dimensional trench array with a plurality of segments defined therein. Each of the plurality of segments has an array of a plurality of recesses extending along the substrate, where the plurality of segments are rotationally symmetric about a center of the two-dimensional trench array. A first conducting layer is presented over the surface and a bottom and sidewalls of the recesses and is insulated from the substrate by a first dielectric layer. A second conducting layer is presented over the first conducting layer and is insulated by a second dielectric layer. First and second contacts respectively connect to an exposed top surface of the first conducting layer and second conducting layer. A third contact connects to the substrate within a local region to the capacitor structure.