Various embodiments of the present application are directed towards an integrated chip (IC). The IC comprises a trench capacitor overlying a substrate. The trench capacitor comprises a plurality of capacitor electrode structures, a plurality of warping reduction structures, and a plurality of capacitor dielectric structures. The plurality of capacitor electrode structures, the plurality of warping reduction structures, and the plurality of capacitor dielectric structures are alternatingly stacked and define a trench segment that extends vertically into the substrate. The plurality of capacitor electrode structures comprise a metal component and a nitrogen component. The plurality of warping reduction structures comprise the metal component, the nitrogen component, and an oxygen component.

The invention provides a metal oxide semiconductor (MOS) capacitor structure, which includes a counter-doping region in the channel region directly below the gate. Between the deep ion well and the counter-doping region is a semiconductor region. The doping concentration of the semiconductor region is lower than that of the deep ion well. The P-type well ion implantation processes in the active region of the device can be omitted, so the production cost is lower, and the dosage of the counter-doping region can be reduced, which improves the time-dependent dielectric collapse (TDDB) issue.

A chip package includes a first integrated-circuit (IC) chip; a second integrated-circuit (IC) chip over the first integrated-circuit (IC) chip; a connector over the first integrated-circuit (IC) chip and on a same horizontal level as the second integrated-circuit (IC) chip, wherein the connector comprises a substrate over the first integrated-circuit (IC) chip and a plurality of through vias vertically extending through the substrate of the connector; a polymer layer over the first integrated-circuit (IC) chip, wherein the polymer layer has a portion between the second integrated-circuit (IC) chip and connector, wherein the polymer layer has a top surface coplanar with a top surface of the second integrated-circuit (IC) chip, a top surface of the substrate of the connector and a top surface of each of the plurality of through vias; and an interconnection scheme on the top surface of the polymer layer, the top surface of the second integrated-circuit (IC) chip, the top surface of the connector and the top surface of each of the plurality of through vias.

A semiconductor device includes a major element including a first semiconductor region, a first electrode, a second electrode, a first gate electrode, and a first insulating member being positioned between the first gate electrode and the first semiconductor region, and a recording element electrically connected with the first electrode. The recording element records, as analog data, a maximum value of a change amount dV/dt of a voltage of the first electrode over time.

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.

An integrated device comprises an electrically conductive substrate having an upper surface comprising a recess and a lower surface for contacting the device, a multi-layer stack provided on the upper surface of the substrate and lining the recess, and an electrically conductive layer for contacting the device provided on the multi-layer stack. The multi-layer stack comprises a first, a second, a third and a fourth dielectric layer. Immediately adjacent dielectric layers have different bandgaps to trap charge carriers at respective interfaces between the dielectric layers during operation of the device.

RC-network components that include a substrate and capacitor having a thin-film top electrode portion at a surface on one side of the substrate. The low ohmic semiconductor substrate is doped to contribute 5% or less to the resistance of the RC-network component. The resistance provided in series with the capacitor is controlled by providing a contact plate, spaced from the thin-film top electrode portion by an insulating layer, and a set of one or more bridging contacts passing through openings in the insulating layer. The bridging contacts electrically interconnect the thin-film top electrode portion and the contact plate. Different resistance values can be set by appropriate selection of the number of bridging contacts. The openings are elongated thereby reducing temperature concentration at their periphery. Correspondingly, the bridging contacts have an elongated cross-sectional shape.

Proposed are a deep trench capacitor and a method of manufacturing the same that compensate for a thin thickness in bottom corner areas of an oxide film (e.g., SiO.sub.2) grown by thermal oxidation in a deep trench to prevent a deterioration in breakdown voltage characteristics due to electric field concentration in the corner areas of the oxide film, or that relatively flatten widthwise inner sidewalls of the deep trench to improve the breakdown voltage characteristics and gap-fill characteristics of a device.

In one embodiment a method of forming a compressive polycrystalline semiconductive material layer is disclosed. The method comprises forming a polycrystalline semiconductive seed layer over a substrate and forming a silicon layer by depositing silicon directly on the polycrystalline silicon seed layer under amorphous process conditions at a temperature below 600 C.

A semiconductor device is formed by forming a deep trench in a substrate and a dielectric liner on sidewalls of the deep trench. A first undoped polysilicon layer is formed on the semiconductor device, extending into the deep trench on the dielectric liner, but not filling the deep trench. Dopants are implanted into the first polysilicon layer. A second layer of polysilicon is formed on the first layer of polysilicon. A thermal drive anneal activates and diffuses the dopants. In one version, the dielectric liner is removed at the bottom of the deep trench before the first polysilicon layer is formed, so that the polysilicon in the deep trench provides a contact to the substrate. In another version, the polysilicon in the deep trench is isolated from the substrate by the dielectric liner.