A memory device includes a page made up of plural memory cells arranged in a column on a substrate. A page write operation is performed to hold positive hole groups generated by an impact ionization phenomenon, in a channel semiconductor layer by controlling voltages applied to a first gate conductor layer, a second gate conductor layer, a first impurity layer, and a second impurity layer of each memory cell contained in the page and a page erase operation is performed to remove the positive hole groups out of the channel semiconductor layer by controlling voltages applied to the first gate conductor layer, the second gate conductor layer, the first impurity layer, and the second impurity layer. The first impurity layer of the memory cell is connected with a source line, the second impurity layer is connected with a bit line, one of the first gate conductor layer and the second gate conductor layer is connected with a word line, and another is connected with a drive control line. The bit line is connected to a sense amplifier circuit via a switch circuit. At least one of word lines is selected and a refresh operation is performed to return the voltage of the channel semiconductor layer of the selected word line to the first data retention voltage by controlling voltages applied to the selected word line, the drive control line, the source line, and the bit line and thereby forming the positive hole groups by an impact ionization phenomenon in the channel semiconductor layer of the memory cell in which the voltage of the channel semiconductor layer is set to the first data retention voltage using the page write operation. The refresh operation is performed, with the switch circuit kept in a nonconducting state, concurrently with a page read operation of reading page data of a first memory cell group belonging to a first page into the sense amplifier circuit.

A P layer 2 having a band shape is on an insulating substrate 1. An N.sup.+ layer 3a connected to a first source line SL1 and an N.sup.+ layer 3b connected to a first bit line are on respective sides of the P layer 2 in a first direction parallel to the insulating substrate. A first gate insulating layer 4a surrounds a portion of the P layer 2 connected to the N.sup.+ layer 3a, and a second gate insulating layer 4b surrounds the P layer 2 connected to the N.sup.+ layer 3b. A first gate conductor layer 5a connected to a first plate line and a second gate conductor layer 5b connected to a second plate line are isolated from each other and cover two respective side surfaces of the first gate insulating layer 4a in a second direction perpendicular to the first direction. A third gate conductor layer 5c connected to a first word line surrounds the second gate insulating layer 4b. These components constitute a dynamic flash memory.

A semiconductor structure includes a substrate with a plurality of word line trenches and source/drain regions each adjacent to each word line trench; a word line located in the word line trench, which includes a first conductive layer located at a bottom of the word line trench, a single junction layer and a second conductive layer stacked in sequence, in which a projection of the word line on a sidewall of the word line trench and the projection of the source/drain region on the sidewall of the word line trench have an overlapping region with a preset height, and when a voltage applied to the word line is less than a preset voltage, a resistance of the single junction layer is greater than the preset resistance, to make the first conductive layer and the second conductive layer disconnected.

A semiconductor device that is suitable for miniaturization and higher density is provided. A semiconductor device includes a first transistor over a semiconductor substrate, a second transistor including an oxide semiconductor over the first transistor, and a capacitor over the second transistor. The capacitor includes a first conductor, a second conductor, and an insulator. The second conductor covers a side surface of the first conductor with an insulator provided therebetween.

Embodiments herein relate to vertical contacts for semiconductor devices. For instance, a memory device having vertical contacts can comprise a substrate including circuitry components, a vertical stack of layers formed from repeating iterations of a group of layers disposed on the substrate, the group of layers comprising a first dielectric material layer, a semiconductor material layer, and a second dielectric material layer including horizontal conductive lines formed along a horizontal plane in the second dielectric material layer, and vertical contacts coupled to the horizontal conductive lines, the vertical contacts extending along a vertical plane within the vertical stack of layers to directly electrically couple the horizontal conductive lines to the circuitry components.

A semiconductor device includes a first transistor formed on a first side of a substrate. The semiconductor device includes a first power rail structure vertically disposed over the first transistor, a second power rail structure vertically disposed over the first power rail structure, and a memory portion vertically disposed over the second power rail structure. The first power rail structure, and a second power rail structure, and the memory portion are all disposed on a second side of the substrate opposite to the first side.

A method for manufacturing a semiconductor structure includes: providing a base; forming multiple discrete first mask layers on the base; forming multiple sidewall layers, in which each sidewall layer is configured to encircle one of the first mask layers, and each sidewall layer is connected to closest sidewall layers, the side walls, away from the first mask layers, of multiple connected sidewall layers define initial first vias and each of the initial first vias is provided with chamfers; removing the first mask layers, and each sidewall layer defines a second via; after removing the first mask layers, forming repair layers which are located on the side walls, away from the second vias, of the sidewall layers and fill the chamfers of the initial first vias to form first vias; and etching the base along the first vias and the second vias to form capacitor holes on the base.

A semiconductor device is provided. The semiconductor device includes a plurality of lower electrodes arranged on a semiconductor substrate in a honeycomb structure; and a support connected to the plurality of lower electrodes and defining a plurality of open areas through which the plurality of lower electrodes are exposed. A center point of each of the plurality of open areas is arranged at a center point of a triangle formed by center points of three corresponding neighboring lower electrodes among the plurality of lower electrodes.

An object of one embodiment of the present invention is to propose a memory device in which a period in which data is held is ensured and memory capacity per unit area can be increased. In the memory device of one embodiment of the present invention, bit lines are divided into groups, and word lines are also divided into groups. The word lines assigned to one group are connected to the memory cell connected to the bit lines assigned to the one group. Further, the driving of each group of bit lines is controlled by a dedicated bit line driver circuit of a plurality of bit line driver circuits. In addition, cell arrays are formed on a driver circuit including the above plurality of bit line driver circuits and a word line driver circuit. The driver circuit and the cell arrays overlap each other.

Semiconductor memory devices may include first and second stacks on a substrate and first and second interconnection lines on the first and second stacks. Each of the first and second stacks may include semiconductor patterns vertically stacked on the substrate, conductive lines connected to the semiconductor patterns, respectively, and a gate electrode that is adjacent to the semiconductor patterns and extends in a vertical direction. The first stack may include a first conductive line and a first gate electrode, and the second stack may include a second conductive line and a second gate electrode. Lower surfaces of the first and second conductive lines may be coplanar. The first interconnection line may be electrically connected to at least one of the first and second conductive lines. The second interconnection line may be electrically connected to at least one of the first and second gate electrodes.