An integrated circuit device includes: a substrate including active regions; a device isolation film defining the active regions; a word line arranged over the active regions and the device isolation film and extending in a first horizontal direction; and a gate dielectric film arranged between the substrate and the word line and between the device isolation film and the word line, in which, in a second horizontal direction orthogonal to the first horizontal direction, a width of a second portion of the word line over the device isolation film is greater than a width of a first portion of the word line over the active regions. To manufacture the integrated circuit device, an impurity region is formed in the substrate and the device isolation film by implanting dopant ions into the substrate and the device isolation film, and a thickness of a portion of the impurity region is reduced.

A semiconductor device includes bit line structures disposed on a substrate, each bit line structure comprising a bit line and an insulating spacer structure, buried contacts which fill lower portions of spaces between bit line structures in the substrate, and landing pads which fill upper portions of the spaces, extend from upper surfaces of the buried contacts to upper surfaces of the bit line structures, and are spaced apart from each other by insulating structures. A first insulating structure is disposed between a first landing pad and a first bit line structure. The first insulating structure includes a sidewall extending along a sidewall of the first landing pad toward the substrate. In a direction extending toward the substrate, the sidewall of the first insulating structure gets closer to a first sidewall of the first bit line structure.

Memory devices may include a source region, channels, a gate insulation layer pattern, a selection gate pattern, a first gate pattern, a second gate pattern and a drain region. The source region may include first impurities having a first conductivity type at an upper portion of a substrate. The channels may contact the source region. Each of the channels may extend in a vertical direction that is perpendicular to an upper surface of the substrate. The selection gate pattern may be on sidewalls of the channels. The first gate pattern may be on the sidewalls of the channels. The first gate pattern may be a common electrode of all of multiple channels. The second gate patterns may be on the sidewalls of the channels. The drain region may include second impurities having a second conductivity type that is different from the first conductivity type at an upper portion of each of the channels.

The present application provides a semiconductor structure and a manufacturing method thereof, relates to the technical field of semiconductors. The manufacturing method of a semiconductor structure includes: providing a substrate; forming a plurality of laminated structures arranged at intervals on the substrate, the laminated structure includes a first conductive layer, an insulating layer, and a second conductive layer, and at least one of the first conductive layer and the second conductive layer is a semi-metal layer; forming a channel layer covering the laminated structures, and a dielectric layer covering the channel layer; and forming word lines (WLs) extending along a first direction, the WL includes a plurality of contact parts and a connecting part connecting adjacent contact parts, the contact part surrounds and is in contact with a side surface of the dielectric layer, and the contact part is opposite to at least a part of the insulating layer.

Since power source voltages are different depending on circuits used for devices, a circuit for outputting at least two or more power sources is additionally prepared. An object is to unify outputs of the power source voltages. A transistor using an oxide semiconductor is provided in such a manner that electrical charge is retained in a node where the transistor and a capacitor are electrically connected to each other, a reset signal is applied to a gate of the transistor to switch the states of the transistor from off to on, and the node is reset when the transistor is on. A circuit configuration that generates and utilizes a potential higher than or equal to a potential of a single power source can be achieved.

A semiconductor device with a small variation in characteristics is provided. The semiconductor device includes a first insulator, a transistor over the first insulator, a second insulator over the transistor, a third insulator over the second insulator, a fourth insulator over the third insulator, and an opening region. The opening region includes the second insulator, the third insulator over the second insulator, and the fourth insulator over the third insulator. The third insulator includes an opening reaching the second insulator. The fourth insulator is in contact with a top surface of the second insulator inside the opening.

A semiconductor memory device includes a semiconductor substrate a gate structure extending in a vertical direction on the semiconductor device, a plurality of charge trap layers spaced apart from each other in the vertical direction and each having a horizontal cross-section with a first ring shape surrounding the gate structure, a plurality of semiconductor patterns spaced apart from each other in the vertical direction and each having a horizontal cross-section with a second ring shape surrounding the plurality of charge trap layers, a source region and a source line at one end of each of the plurality of semiconductor patterns in a horizontal direction, and a drain region and a drain line at an other end of each of the plurality of semiconductor patterns in the horizontal direction. The gate structure may include a gate insulation layer and a gate electrode layer.

The present disclosure provides a semiconductor device with a composite dielectric structure and a method for forming the semiconductor device. The semiconductor device includes a conductive contact disposed over a semiconductor substrate, and a first dielectric layer disposed over the conductive contact. A top surface of the conductive contact is exposed by an opening. The semiconductor device also includes a bottom electrode extending along sidewalls of the opening and the top surface of the conductive contact, and a top electrode disposed over the bottom electrode and separated from the bottom electrode by a dielectric structure. The dielectric structure includes a second dielectric layer and dielectric portions disposed over the second dielectric layer. The dielectric portions cover top corners of the opening and extend partially along the sidewalls of the opening.

In a memory device, pages are arrayed in a column direction, each page constituted by memory cells arrayed in row direction on an insulating substrate. Each memory cell includes a zonal P layer. N.sup.+ layers continuous with a source line and a bit line respectively are on both sides of the P layer. Gate insulating layers surround part of the P layer continuous with the N.sup.+ layer and part of the P layer continuous with the N.sup.+ layer 3b, respectively. One side surface and the other side surface of the gate insulating layer are covered with a gate conductor layer continuous with a first plate line and a gate conductor layer continuous with a second plate line, respectively. A gate conductor layer continuous with a word line surrounds the gate insulating layer.

A memory device includes pages, each being composed of a plurality of memory cells arrayed on a substrate in row form. The memory device controls voltages to be applied to a first gate conductor layer, a second gate conductor layer, a first impurity region, and a second impurity region of each of the memory cells included in the pages to perform a page write operation of holding a hole group formed by an impact ionization phenomenon or a gate induced drain leakage current in a channel semiconductor layer, and controls voltages to be applied to the first gate conductor layer, the second gate conductor layer, the third gate conductor layer, the fourth gate conductor layer, the first impurity region, and the second impurity region to perform a page erase operation of removing the hole group out of the channel semiconductor layer. The first impurity layer of each of the memory cells is connected to a source line, the second impurity region is connected to a bit line, one of the first gate conductor layer and the second gate conductor layer is connected to a word line, and the other is connected to a first driving control line. The bit line is connected to a sense amplifier circuit via a switching circuit. When in a page read operation, the memory device reads page data in a memory cell group selected by the word line to the bit line, and performs charge sharing between the bit line and a charge sharing node of the switching circuit opposite to the bit line to accelerate a read determination by the sense amplifier circuit.