The present disclosure relates to a semiconductor device including a conductive contact having a tapering profile and a method for preparing the semiconductor device. The semiconductor device includes a conductive layer disposed over a semiconductor substrate, and a conductive contact disposed over the conductive layer. The semiconductor device also includes a conductive line disposed over the conductive contact. An upper portion of the conductive contact has a tapering profile in a first cross-sectional view along a longitudinal axis of the conductive line, and the upper portion of the conductive contact has a non-tapering profile in a second cross-sectional view along a line orthogonal to the longitudinal axis of the conductive line.

A method for fabricating a vertical memory device includes: forming a memory cell array that includes a vertical thyristor and a word line over a first substrate; forming a peripheral circuit unit in a second substrate; bonding the memory cell array with the peripheral circuit unit; removing the first substrate to expose one side of the vertical thyristor; and forming a bit line that is coupled to the one side of the vertical thyristor and the peripheral circuit unit.

To compensate switching of a dielectric component of a non-linear polar material based capacitor, an explicit dielectric capacitor is added to a memory bit-cell and controlled by a signal opposite to the signal driven on a plate-line.

A method of manufacturing a dynamic random access memory is provided and includes: forming a hard mask layer on a substrate; forming an opening in the hard mask layer and the substrate; forming a dielectric layer on a sidewall of the opening; forming a first part of a buried word line in a lower part of the opening; forming a hard mask layer on a top surface of the hindering layer, where the hindering layer has overhangs covering top corners of the hard mask layer; depositing a first barrier layer on the substrate through hindrance of the overhangs, where the first barrier layer covers the hindering layer and a top surface of the first part and exposes the dielectric layer on the sidewall of the opening; and forming a first conductive layer in the opening, where a sidewall of the first conductive layer contacts the dielectric layer.

A method of manufacturing a DRAM includes proving a substrate having active regions. First bit line structures are buried in the substrate. Each of first bit line structures extends along a first direction. Every two of the first bit line structures are disposed between two neighboring ones of the active regions arranged along a second direction. A plurality of pillar structures are formed arranged along the first direction by dividing each of the active regions. Second bit line structures are formed. Each of the second bit line structures is located between the pillar structures of a corresponding one of the active regions and extends through the corresponding one of the active regions along the second direction to be disposed on the first bit line structures at two sides of the corresponding one of the active regions and be electrically connected to the first bit line structures below.

A semiconductor memory device includes a memory cell array of a three-dimensional structure including a plurality of memory cells repeatedly arranged in a first horizontal direction and a second horizontal direction that are parallel with a main surface of a substrate and cross each other on the substrate and in a vertical direction perpendicular to the main surface, wherein each of the plurality of memory cells includes three transistors. A method of manufacturing a semiconductor memory device includes forming simultaneously a plurality of memory cells arranged in a row in a vertical direction on a substrate, wherein each of the plurality of memory cells includes three transistors.

A method for fabricating floating body memory cells (FBCs), and the resultant FBCs where gates favoring different conductivity type regions are used is described. In one embodiment, a p type back gate with a thicker insulation is used with a thinner insulated n type front gate. Processing, which compensates for misalignment, which allows the different oxide and gate materials to be fabricated is described.

Some embodiments include an integrated assembly having a carrier-sink-structure, and having digit lines over the carrier-sink-structure. Transistor body regions are over the digit lines. Extensions extend from the carrier-sink-structure to the transistor body regions. The extensions are configured to drain excess carriers from the transistor body regions. Lower source/drain regions are between the transistor body regions and the digit lines, and are coupled with the digit lines. Upper source/drain regions are over the transistor body regions, and are coupled with storage elements. Gates are adjacent the transistor body regions. The transistor body regions, lower source/drain regions and upper source/drain regions are together comprised a plurality of transistors. The transistors and the storage elements are together comprised by a plurality of memory cells of a memory array. Some embodiments include methods of forming integrated assemblies.

A semiconductor structure for a DRAM is described having multiple layers of arrays of thyristor memory cells and associated peripheral circuitry. Memory cells in a vertical string extending through the layers have an electrical connection to one terminal of the memory cells in that string. Word lines couple the strings together. Each layer of the array also includes bit line connections to memory cells on that layer. Methods of fabricating the array are described.

Most semiconductor devices manufactured today, have uniform dopant concentration, either in the lateral or vertical device active (and isolation) regions. By grading the dopant concentration, the performance in various semiconductor devices can be significantly improved. Performance improvements can be obtained in application specific areas like increase in frequency of operation for digital logic, various power MOSFET and IGBT ICs, improvement in refresh time for DRAMs, decrease in programming time for nonvolatile memory, better visual quality including pixel resolution and color sensitivity for imaging ICs, better sensitivity for varactors in tunable filters, higher drive capabilities for JFETs, and a host of other applications.