An electrical device including a substrate structure including a relaxed region of alternating layers of at least a first semiconductor material and a second semiconductor material. A first region of the substrate structure includes a first type conductivity semiconductor device having a first strain over a first portion of the relaxed region. A second region of the substrate structure includes a second type conductivity semiconductor device having a second strain over a second portion of the relaxed region. A third region of the substrate structure including a trench capacitor extending into relaxed region, wherein a width of the trench capacitor defined by the end to end distance of the node dielectric for the trench capacitor alternates between at least two width dimensions as a function of depth measured from the upper surface of the substrate structure.

An electrical device including a substrate structure including a relaxed region of alternating layers of at least a first semiconductor material and a second semiconductor material. A first region of the substrate structure includes a first type conductivity semiconductor device having a first strain over a first portion of the relaxed region. A second region of the substrate structure includes a second type conductivity semiconductor device having a second strain over a second portion of the relaxed region. A third region of the substrate structure including a trench capacitor extending into relaxed region, wherein a width of the trench capacitor defined by the end to end distance of the node dielectric for the trench capacitor alternates between at least two width dimensions as a function of depth measured from the upper surface of the substrate structure.

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.

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.

A semiconductor substrate comprises both vertical interconnects and vertical capacitors with a common dielectric layer. The substrate can be suitably combined with further devices to form an assembly. The substrate can be made in etching treatments including a first step on the one side, and then a second step on the other side of the substrate.

A method for forming a split-gate flash memory cell, and the resulting integrated circuit, are provided. A semiconductor substrate having memory cell and capacitor regions are provided. The capacitor region includes one or more sacrificial shallow trench isolation (STI) regions. A first etch is performed into the one or more sacrificial STI regions to remove the one or more sacrificial STI regions and to expose one or more trenches corresponding to the one or more sacrificial STI regions. Dopants are implanted into regions of the semiconductor substrate lining the one or more trenches. A conductive layer is formed filling the one or more trenches. A second etch is performed into the conductive layer to form one of a control gate and a select gate of a memory cell over the memory cell region, and to form an upper electrode of a finger trench capacitor over the capacitor region.

A semiconductor device is provided including a fully depleted silicon-on-insulator (FDSOI) substrate and a charge pump device, wherein the FDSOI substrate comprises a semiconductor bulk substrate, and the charge pump device comprises a transistor device formed in and on the FDSOI substrate, and a trench capacitor formed in the semiconductor bulk substrate and electrically connected to the transistor device. A semiconductor device is further provided including a semiconductor bulk substrate, a first transistor device comprising a first source/drain region, a second transistor device comprising a second source/drain region, a first trench capacitor comprising a first inner capacitor electrode and a first outer capacitor electrode, and a second trench capacitor comprising a second inner capacitor electrode and a second outer capacitor electrode, wherein the first inner capacitor electrode is connected to the first source/drain region and the second inner capacitor electrode is connected to the second source/drain region.

Various embodiments of the present disclosure are directed towards an integrated chip including a substrate comprising first opposing sidewalls defining a first trench and second opposing sidewalls defining a second trench laterally offset from the first trench. A stack of layers comprises a plurality of conductive layers and a plurality of dielectric layers alternatingly stacked with the conductive layers. The stack of layers comprises a first segment in the first trench and a second segment in the second trench. A first lateral distance between the first segment and the second segment aligned with a first surface of the substrate is greater than a second lateral distance between the first segment and the second segment below the first surface of the substrate.