Systems, methods and apparatus are provided for a three-node access device in vertical three-dimensional (3D) memory. An example method includes a method for forming arrays of vertically stacked memory cells, having horizontally oriented access devices and vertically oriented access lines. The method includes depositing alternating layers of a dielectric material and a sacrificial material to form a vertical stack. Forming a plurality of first vertical openings to form elongated vertical, pillar columns with sidewalls in the vertical stack. Conformally depositing a gate dielectric in the plurality of first vertical openings. Forming a conductive material on the gate dielectric. Removing portions of the conductive material to form a plurality of separate, vertical access lines. Repairing a first side of the gate dielectric exposed where the conductive material was removed. Forming a second vertical opening to expose sidewalls adjacent a first region of the sacrificial material. Selectively removing the sacrificial material in the first region to form first horizontal openings. Repairing a second side of the gate dielectric exposed where the sacrificial material was removed in the first region. Depositing a first source/drain region, a channel region, and a second source/drain region in the first horizontal openings.

An integrated circuit device includes a substrate having an active area, bit line structures on the substrate, the bit line structures including an insulating spacer on each sidewall thereof, a buried contact between the bit line structures, the buried contact being connected to the active area, an insulation capping pattern on each of the bit line structures, a barrier conductive layer covering side surfaces of the insulation capping pattern, and an upper surface and side surfaces of the insulating spacer, and a landing pad electrically connected to the buried contact, the landing pad vertically overlapping one of the bit line structures on the insulation capping pattern and the barrier conductive layer.

The present invention provides a semiconductor module, a semiconductor member, and a method for manufacturing the same that make it possible to improve heat dissipation efficiency. This semiconductor module 1 comprises: a power supply unit 40; a RAM unit 50, which is a RAM module having a facing surface disposed so as to face an exposed surface of a logic chip 20 and an exposed surface of the power supply unit 40, the RAM module being disposed across some of a plurality of logic chip signal terminals 22 and some of a plurality of power supply unit power supply terminals 41; and a support substrate 10 having a power feeding circuit capable of feeding electrical power to the logic chip and to the power supply unit 40, one main surface of the support substrate 10 being disposed adjacent to a heat dissipation surface of the RAM unit 50, which is the surface of the RAM unit 50 opposite the facing surface. The support substrate 10 is electrically connected, using the power feeding circuit 12, to at least some of logic chip power supply terminals 21 and the other power supply unit power supply terminals 41. The support substrate 10 has, at positions overlapping the RAM unit 50, heat dissipation vias 11 that penetrate in the thickness direction and come into contact with the heat dissipation surface of the RAM unit 50.

The invention discloses a pattern layout of an active region and a forming method thereof. The feature of the present invention is that in the sub-pattern unit, an appropriate active area pattern is designed according to the bit line pitch (BLP) and the word line pitch (WLP), the active area pattern is a stepped pattern formed by connecting a plurality of rectangular patterns in series, and the active area pattern is arranged along a first direction, the angle between the first direction and the horizontal direction is A. In addition, according to the angle A, the shortest distance (P) between adjacent stepped patterns, the length and width of sub-pattern units, etc., The positions of some stepped active area patterns are adjusted, so that the distance between multiple active area patterns can be consistent when being repeatedly arranged, thereby improving the uniformity of overall pattern distribution.

In a semiconductor device, a first stack is positioned over substrate and includes a first pair of transistors and a second pair of transistors stacked over the substrate. A second stack is positioned over the substrate and adjacent to the first stack. The second stack includes a third pair of transistors and a fourth pair of transistors stacked over the substrate. A first capacitor is stacked with the first and second stacks. A second capacitor is positioned adjacent to the first capacitor and stacked with the first and second stacks. A first group of the transistors in the first and second stacks is coupled to each other to form a static random-access memory cell. A second group of the transistors in the first and second stacks is coupled to the first and second capacitors to form a first dynamic random-access memory (DRAM) cell and a second DRAM cell.

A semiconductor device includes a substrate including a cell region, a peripheral region, and a boundary region therebetween, a cell device isolation pattern on the cell region of the substrate to define cell active patterns, a peripheral device isolation pattern on the peripheral region of the substrate to define peripheral active patterns, and an insulating isolation pattern on the boundary region of the substrate, the insulating isolation pattern being between the cell active patterns and the peripheral active patterns, wherein a bottom surface of the insulating isolation pattern includes a first edge adjacent to a side surface of a corresponding one of the cell active patterns, and a second edge adjacent to a side surface of a corresponding one of the peripheral active patterns, the first edge being at a height lower than the second edge, when measured from a bottom surface of the substrate.

A semiconductor structure and a manufacturing method thereof are provided. The method includes: providing a substrate; forming, on the substrate, a first mask layer having a plurality of strip-shaped first patterns arranged in parallel; forming, on the first mask layer, a second mask layer having a plurality of strip-shaped second patterns arranged in parallel; forming, on the second mask layer, a third mask layer having a plurality of strip-shaped third patterns arranged in parallel, the second patterns overlap with the third patterns, and the second patterns and the third patterns are configured to sever the first patterns at predetermined positions; and performing layer-by-layer etching, using the first mask layer, the second mask layer, and the third mask layer as masks to transfer the first patterns, the second patterns, and the third patterns to the substrate to form an array of discrete active areas.

Some embodiments include an assembly having a stack of first and second alternating levels. The first levels are insulative levels. The second levels are device levels having integrated devices. Each of the integrated devices has a transistor coupled with an associated capacitor, and the capacitor is horizontally offset from the transistor. The transistors have semiconductor channel material, and have transistor gates along the semiconductor channel material. Each of the transistors has a first source/drain region along one side of the semiconductor channel material and coupled with the associated capacitor, and has a second source/drain region. Wordlines extend horizontally along the device levels and are coupled with the transistor gates. Digit lines extend vertically through the device levels and are coupled with the second source/drain regions. Some embodiments include methods of forming integrated structures.

The present disclosure relates to a semiconductor structure and a manufacturing method thereof. The semiconductor structure includes: a substrate including a peripheral region, wherein the peripheral region includes a wire lead-out area, and the substrate is arranged with a plurality of discrete bit line structures; a dielectric layer formed between the adjacent bit line structures, wherein the peripheral region is arranged with a first contact hole; a wire lead-out area with a second through hole; a filling layer filling part of a first contact hole, wherein a remaining part of the first contact hole is defined as a first through hole; a first conductive layer located in the first through hole and the second through hole; and a conductive connecting wire located over the dielectric layer and being in contact with the first conductive layer in the wire lead-out area.

The present disclosure provides a method of preparing a semiconductor structure and a semiconductor structure, which relate to the field of semiconductors. The method includes: setting a top surface of a second conductive layer to be lower than a top surface of a first conductive layer; setting a top surface of a first initial bit line conductive layer to be higher than a top surface of a second initial bit line conductive layer; etching the first initial bit line conductive layer by a first etching process, and performing the first etching process on a part of the second initial bit line conductive layer; etching the first conductive layer by a second etching process, and etching a remaining part of the second initial bit line conductive layer; and forming a bit line contact structure wrapping a void, widths of parts of the bit line contact structure gradually increasing.