After formation of trench capacitors and source and drain regions and gate structures for access transistors, a dielectric spacer is formed on a first sidewall of each source region, while a second sidewall of each source region and sidewalls of drain regions are physically exposed. Each dielectric spacer can be employed as an etch mask during removal of trench top dielectric portions to form strap cavities for forming strap structures. Optionally, selective deposition of a semiconductor material can be performed to form raised source and drain regions. In this case, the raised source regions grow only from the first sidewalls and do not grow from the second sidewalls. The raised source regions can be employed as a part of an etch mask during formation of the strap cavities. The strap structures are formed as self-aligned structures that are electrically isolated from adjacent access transistors by the dielectric spacers.

A multi-layer, crown-shaped MIM capacitor includes a base having therein conductive region, an inter-metal dielectric (IMD) layer on the base, a capacitor trench penetrating through the IMD layer and exposing the conductive region, a capacitor lower electrode structure including a first electrode and a second electrode surrounded by the first electrode, a conductive supporting pedestal within the capacitor trench for fixing and electrically connecting the bottom portions of the first and second electrodes, a capacitor dielectric layer conformally lining the first and second electrodes and a top surface of the conductive supporting pedestal, and a capacitor upper electrode on the capacitor dielectric layer.

A symmetric varactor structure may include a first varactor component. The first varactor component may include a gate operating as a second plate, a gate oxide layer operating as a dielectric layer and a body operating as a first plate of an area modulating capacitor. In addition, doped regions may surround the body of the first varactor component. The first varactor component may be supported on a backside by an isolation layer. The symmetric varactor structure may also include a second varactor component electrically coupled to the backside of the first varactor component through a backside conductive layer.

The present disclosure relates to an integrated chip having an inter-digitated capacitor, and an associated method of formation. In some embodiments, the integrated chip has a plurality of upper electrodes separated from a substrate by a first dielectric layer. A plurality of lower electrodes vertically extend from between the plurality of upper electrodes to locations embedded within the substrate. A charge trapping dielectric layer is arranged between the substrate and the plurality of lower electrodes and between the plurality of upper electrodes and the plurality of lower electrodes. The charge trapping dielectric layer has a plurality of discrete segments respectively lining opposing sidewalls and a lower surface of one of the plurality of lower electrodes.

A semiconductor structure and a method of fabricating thereof are provided. The semiconductor structure includes a substrate and a capacitor structure. The substrate has a first blind hole and a trench. The first blind hole communicates with the trench. The first blind hole has a first depth, and the trench has a second depth smaller than the first depth. The capacitor structure includes a first inner conductor, a first inner insulator, and an outer conductor. The first inner conductor is in the first blind hole. The first inner insulator surrounds the first inner conductor. The outer conductor has a first portion surrounding the first inner insulator and an extending portion extending from the first portion. The first portion is in the first blind hole, and the extending portion is in the trench. The first inner conductor is separated from the outer conductor by the first inner insulator.

A method for fabricating a semiconductor device includes the steps of first providing a substrate comprising a non-metal-oxide semiconductor capacitor (non-MOSCAP) region and a MOSCAP region, forming a first fin-shaped structure on the MOSCAP region, forming a doped layer on the substrate of the non-MOSCAP region and the first fin-shaped structure on the MOSCAP region, removing the doped layer on the non-MOSCAP region, and then performing an anneal process to drive dopants from the doped layer into the first fin-shaped structure.

A memory device includes at least one memory cell. The memory cell includes first and second transistors, and first and second capacitors. The first transistor is coupled to a source line. The second transistor is coupled to the first transistor and a bit line. The first capacitor is coupled to a word line and the second transistor. The second capacitor is coupled to the second transistor and an erase gate.

An arrangement for making electrical contact to a vertical capacitor having top and bottom metal layers separated by a dielectric, and at least one trench. Recesses are formed in an oxide layer over the capacitor to provide access to the top and bottom metal layers. The recesses include contacting portions preferably positioned such that there is no overlap between them and any of the trenches. Metal in the recesses, preferably copper, forms electrical contacts to the vertical capacitor's metal layers and enables reliable bonding to copper metallization on other layers such as an ROIC layer. Dummy capacitors may be tiled on portions of the IC where there are no vertical capacitors, preferably with the top surfaces of their top metal at a height approximately equal to that of the top surface of the vertical capacitor's top metal, thereby enabling the IC to be planarized with a uniform planarization thickness.

The present disclosure relates to an integrated chip having a deep trench capacitor with serrated sidewalls defining curved depressions, and a method of formation. In some embodiments, the integrated chip includes a substrate having a trench with serrated sidewalls defining a plurality of curved depressions. A layer of dielectric material conformally lines the serrated sidewalls, and a layer of conductive material is arranged within the trench and is separated from the substrate by the layer of dielectric material. The layer of dielectric material is configured as a capacitor dielectric between a first electrode comprising the layer of conductive material and a second electrode arranged within the substrate. The serrated sidewalls of the layer of conductive material increase a surface area of exterior surfaces of the layer of conductive material, thereby increasing a capacitance of the capacitor per unit of depth

The present disclosure relates to an inter-digitated capacitor that can be formed along with split-gate flash memory cells and that provides for a high capacitance per unit area, and a method of formation. In some embodiments, the inter-digitated capacitor has a well region disposed within an upper surface of a semiconductor substrate. A plurality of trenches vertically extend from the upper surface of the semiconductor substrate to positions within the well region. Lower electrodes are arranged within the plurality of trenches. The lower electrodes are separated from the well region by a charge trapping dielectric layer arranged along inner-surfaces of the plurality of trenches. A plurality of upper electrodes are arranged over the semiconductor substrate at locations laterally separated from the lower electrodes by the charge trapping dielectric layer and vertically separated from the well region by a first dielectric layer.