Various embodiments of the present application are directed towards a semiconductor device comprising a trench capacitor, the trench capacitor comprising a plurality of lateral protrusions. In some embodiments, the trench capacitor comprises a dielectric structure over a substrate. The dielectric structure may comprise a plurality of dielectric layers overlying the substrate. The dielectric structure may comprise a plurality of lateral recesses. In some embodiments, the plurality of lateral protrusions extend toward and fill the plurality of lateral recesses. By forming the trench capacitor with the plurality of lateral protrusions filling the plurality of lateral recesses, the surface area of the capacitor is increased without increasing the depth of the trench. As a result, greater capacitance values may be achieved without necessarily increasing the depth of the trench and thus, without necessarily increasing the size of the semiconductor device.

An integrated circuit (IC) structure having a plurality of backend double-walled capacitors (DWCs) are described. In an example, a first interconnect layer is disposed over a substrate and a second interconnect layer is disposed over the first interconnect layer. In the example, a plurality of DWCs are disposed in the first interconnect layer or the second interconnect layer to provide capacitance to assist the first interconnect layer and the second interconnect layer in providing electrical signal routing and power distribution to one or more devices in the IC structure. In examples, the IC structure includes a logic IC or a coupling substrate.

A semiconductor device includes a semiconductor substrate having a cell region and a dummy region surrounding the cell region, a plurality of memory pillar structures, and a supporting layer. The memory pillar structures are on the cell region. The supporting layer is over the semiconductor substrate, interconnecting the memory pillar structures, and having a plurality of first and second opening patterns on the cell region. A first number of the memory pillar structures surround each of the first opening patterns, and a second number of the memory pillar structures surround each of the second opening patterns. The first opening patterns are different from the second opening patterns, the first number is different from the second number, and at least one of the first opening patterns and at least one of the second opening patterns are on a central portion of the cell region.

A semiconductor device includes conductive pillars on a semiconductor substrate, a first support pattern that contacts first portions of lateral surfaces of the conductive pillars and connects the conductive pillars to each other, the first support pattern including first support holes that expose second portions of the lateral surfaces of the conductive pillars, a capping conductive pattern that contacts the second portions of the lateral surfaces of the conductive pillars and exposes the first support pattern, the second portions of the lateral surfaces of the conductive pillars being in no contact with the first support pattern, and a dielectric layer that covers the first support pattern and the capping conductive pattern, the dielectric layer being spaced apart from the conductive pillars.

A semiconductor device may include a bottom sub-electrode on a substrate, a top sub-electrode on the bottom sub-electrode, a dielectric layer covering the bottom and top sub-electrodes, and a plate electrode on the dielectric layer. The top sub-electrode may include a step extending from a side surface thereof, which is adjacent to the bottom sub-electrode, to an inner portion of the top sub-electrode. The top sub-electrode may include a lower portion at a level that is lower than the step and an upper portion at a level which is higher than the step. A maximum width of the lower portion may be narrower than a minimum width of the upper portion. The maximum width of the lower portion may be narrower than a width of a top end of the bottom sub-electrode. The bottom sub-electrode may include a recess in a region adjacent to the top sub-electrode.

Memory devices in which a memory cell includes a thin film select transistor and a capacitor (1TFT-1C). A 2D array of metal-insulator-metal capacitors may be fabricated over an array of the TFTs. Adjacent memory cells coupled to a same bitline may employ a continuous stripe of thin film semiconductor material. An isolation transistor that is biased to remain off may provide electrical isolation between adjacent storage nodes of a bitline. Wordline resistance may be reduced with a wordline shunt fabricated in a metallization level and strapped to gate terminal traces of the TFTs at multiple points over a wordline length. The capacitor array may occupy a footprint over a substrate. The TFTs providing wordline and bitline access to the capacitors may reside substantially within the capacitor array footprint. Peripheral column and row circuitry may employ FETs fabricated over a substrate substantially within the capacitor array footprint.

Disclosed are a semiconductor memory device and a method of manufacturing the same. The semiconductor memory device includes a device isolation layer defining active regions of a substrate, and gate lines buried in the substrate and extending across the active regions. Each of the gate lines includes a conductive layer, a liner layer disposed between and separating the conductive layer and the substrate, and a first work function adjusting layer disposed on the conductive layer and the liner layer. The first work function adjusting layer includes a first work function adjusting material. A work function of the first work function adjusting layer is less than those of the conductive layer and the liner layer.

Some embodiments include an integrated memory assembly having a first memory array deck over a second memory array deck. A first series of conductive lines extends across the first memory array deck, and a second series of conductive lines extends across the second memory array deck. A first conductive line of the first series and a first conductive line of the second series are coupled with a first component through a first conductive path. A second conductive line of the first series and a second conductive line of the second series are coupled with a second component through a second conductive path. The first and second conductive lines of the first series extend through first isolation circuitry to the first and second conductive paths, respectively; and the first and second conductive lines of the second series extend through second isolation circuitry to the first and second conductive paths, respectively.

A method for fabricating a semiconductor device is provided. The method includes the actions of: providing a substrate comprising a preliminary pattern formed thereon; forming an opening through the preliminary pattern to expose a conductive portion in the substrate; forming a spacer on a sidewall of the opening; performing an wet etching process to form a hole in the conductive portion; removing the spacer; and depositing a conductive pattern over the sidewall of the opening and a surface of the hole.

Some embodiments include an integrated assembly having a base comprising sense-amplifier-circuitry, a first deck over the base, and a second deck over the first deck. The first deck includes a first portion of a first array of first memory cells, and includes a first portion of a second array of second memory cells. The second deck includes a second portion of the first array of the first memory cells, and includes a second portion of the second array of the second memory cells. A first digit line is associated with the first array, and a second digit line is associated with the second array. The first and second digit lines are comparatively coupled with one another through the sense-amplifier-circuitry.