A semiconductor device comprises, a substrate, a first capacitor structure including a plurality of first storage electrodes on the substrate, a first upper electrode on the first storage electrodes and a first capacitor dielectric layer between the plurality of first storage electrodes and the first upper electrode, and a first lower electrode between the first capacitor structure and the substrate and electrically connected with the first capacitor structure. The plurality of first storage electrodes include a first normal storage electrode and a first dummy storage electrode, which are spaced apart from each other. The first normal storage electrode is electrically connected with the first lower electrode, and the first dummy storage electrode is not electrically connected with the first lower electrode.

A semiconductor device including a substrate including a cell area and a peripheral circuit area, a plurality of cell transistors in the cell area, a peripheral circuit in the peripheral circuit area, a first etch stop film covering the cell transistors, a second etch stop film covering the peripheral circuit and defining a bottom plug space passing therethrough, a capacitor structure in the cell area and including lower electrodes passing through the first etch stop film and respectively connected to the cell transistors, a peripheral circuit contact in the peripheral circuit area, the peripheral circuit contact passing through the second etch stop film and electrically connected to the peripheral circuit, and an insulating liner on a side wall portion of the second etch stop film defining the bottom plug space, the insulating liner surrounding a portion of a side wall of the peripheral circuit contact may be provided.

Disclosed is a semiconductor device comprising a peripheral word line disposed on a substrate, a lower dielectric pattern covering the peripheral word line and including a first part that covers a lateral surface of the peripheral word line and a second part that covers a top surface of the peripheral word line, a contact plug on one side of the peripheral word line and penetrating the first and second parts, and a filling pattern in contact with the second part of the lower dielectric pattern and penetrating at least a portion of the second part. The contact plug includes a contact pad disposed on a top surface of the lower dielectric pattern, and a through plug penetrating the first and second parts. The filling pattern surrounds a lateral surface of the contact pad. The first and second parts include the same material.

A memory structure including a substrate, a bit line structure, a contact structure, a stop layer, and a capacitor structure is provided. The substrate includes a memory array region. The bit line structure is located in the memory array region and located on the substrate. The contact structure is located in the memory array region and located on the substrate on one side of the bit line structure. The stop layer is located in the memory array region and located above the bit line structure. The capacitor structure is located in the memory array region. The capacitor structure passes through the stop layer and is electrically connected to the contact structure. A bottom surface of the capacitor structure is lower than a bottom surface of the stop layer.

The present disclosure relates to the technical field of semiconductor manufacturing, and provides a method of manufacturing a semiconductor structure. The method of manufacturing a semiconductor structure includes: providing a substrate; forming a mask layer on the substrate; removing a part of the mask layer on a non-array region; forming a first oxide layer on the non-array region; removing a part of the first oxide layer on a first transistor region, to expose a top surface of the first transistor region; forming an epitaxial layer on the exposed top surface of the first transistor region; removing a part of the first oxide layer on a second transistor region; and forming a second oxide layer on the second transistor region and the epitaxial layer.

A memory device architecture, and method of fabricating a three dimensional device are provided. The memory device architecture may include a plurality of memory blocks, arranged in an array, wherein a given memory block comprises: a cell region, the cell region comprising a three-dimensional array of memory cells, arranged in a plurality of n memory cell layers; and a staircase region, the staircase region being disposed adjacent to at least a first side of the cell region, the staircase region comprising a signal line assembly that is coupled to the three-dimensional array of memory cells.

The present disclosure provides a method for preparing a semiconductor device structure. The method includes forming a pad oxide layer over a semiconductor substrate; forming a pad nitride layer over the pad oxide layer; forming a shallow trench penetrating through the pad nitride layer and the pad oxide layer and extending into the semiconductor substrate; forming a first liner, a second liner and a third liner over sidewalls and a bottom surface of the semiconductor substrate in the shallow trench; filling a remaining portion of the shallow trench with a trench filling layer over the third liner; and planarizing the second liner, the third liner and the trench filling layer to expose the pad nitride layer. The first liner and the remaining portions of the second liner, the third liner and the trench filling layer collectively form a shallow trench isolation (STI) structure in an array area.

A semiconductor device may include a cell capacitor including first lower electrodes, a first upper support layer pattern, a first dielectric layer, and a first upper electrode. The decoupling capacitor may include second lower electrodes, a second upper support layer pattern, a second dielectric layer, and a second upper electrode. The first and second lower electrodes may be arranged in a honeycomb pattern at each vertex of a hexagon and a center of the hexagon. The first upper support layer pattern may be connected to upper sidewalls of the first lower electrodes. The first upper support layer pattern may correspond to a first plate defining first openings. The second upper support layer pattern may be connected to upper sidewalls of the second electrodes. The second upper support layer pattern may correspond to a second plate defining second openings having a shape different from a shape of the first opening.

DRAM circuitry comprises a memory array comprising memory cells individually comprising a transistor and a charge-storage device. The transistors individually comprise two source/drain regions having a gate there-between that is part of one of multiple wordlines of the memory array. One of the source/drain regions is electrically coupled to one of the charge-storage devices. The other of the source/drain regions is electrically coupled to one of multiple sense lines of the memory array. Peripheral circuitry comprises wordline-driver transistors having gates which individually comprise one of the wordlines and comprises sense-line-amplifier transistors having gates which individually comprise one of the sense lines. The sense-line-amplifier transistors and the wordline-driver transistors individually are a finFET having at least one fin comprising a channel region of the respective finFET. The sense-line-amplifier transistors and the wordline-driver transistors individually comprise two source/drain regions that individually comprise conductively-doped epitaxial semiconductor material that is adjacent one of two laterally-opposing sides of the at least one fin in a vertical cross-section. Methods are also disclosed.

A semiconductor device includes a substrate that includes peripheral and logic cell regions, a device isolation layer that defines a first active pattern on the peripheral region and second and third active patterns on the logic cell region, and first to third transistors on the first to third active patterns. Each of the first to third transistors includes a gate electrode, a gate spacer, a source pattern and a drain pattern. The second active pattern includes a semiconductor pattern that overlaps the gate electrode. At least a portion of a top surface of the device isolation layer is higher than a top surface of the second and third active patterns. A profile of the top surface of the device isolation layer includes two or more convex portions between the second and third active patterns.