A semiconductor memory device including a transistor body extending in a first horizontal direction and including a first source/drain region, a single-crystal channel layer, and a second source/drain region sequentially arranged in the first horizontal direction, a gate electrode layer extending in a second horizontal direction orthogonal to the first horizontal direction and covering upper and lower surfaces of the single-crystal channel layer, a bit line connected to the first source/drain region, extending in a vertical direction, and having a first width in the second horizontal direction, a spacer covering upper and lower surfaces of the first source/drain region and having a second width greater than the first width, and a cell capacitor on a side opposite to the bit line with respect to the transistor body in the first horizontal direction and including lower and upper electrode layers and a capacitor dielectric layer therebetween may be provided.

According to some embodiments of the present inventive concept, a semiconductor memory device includes a plurality of mold insulating layers on a substrate and spaced apart from one another, a plurality of semiconductor patterns which are between respective ones of the plurality of mold insulating layers adjacent to each other, a plurality of gate electrodes, on respective ones of the plurality of semiconductor patterns, an information storage element which includes a first electrode electrically connected to each of the plurality of semiconductor patterns, a second electrode on the first electrode, and a capacitor dielectric film between the first electrode and the second electrode, a bit line on the substrate and contacts the semiconductor pattern, and an insulating buffer film between the first electrodes and the second electrode and on a sidewall of a respective one of the plurality of mold insulating layers.

A semiconductor memory device includes a word line extended parallel to a top surface of a semiconductor substrate, a channel pattern crossing the word line and having a long axis parallel to the top surface, a bit line extended perpendicular to the top surface and in contact with a first side surface of the channel pattern, and a data storage element in contact with a second side surface of the channel pattern opposite to the first side surface. The channel pattern includes a first dopant region adjacent to the bit line, a second dopant region adjacent to the data storage element, and a channel region between the first and second dopant regions and overlapped with the word line. At least one of the first and second dopant regions includes a low concentration region adjacent to the channel region, and a high concentration region spaced apart from the channel region.

Capacitors that can be formed fully on an integrated circuit (IC) chip are described in this disclosure. An IC chip includes a metal-oxide-silicone (MOS) capacitor formed from a MOS transistor having a drain terminal, a source terminal, a gate terminal, and a body terminal. The drain terminal and the source terminal are not electrically connected to any other node, and the gate terminal and the body terminal form respective first and second terminals of the MOS capacitor. The IC chip also includes an electrical conductor coupled to one of the gate terminal or the body terminal of the MOS transistor and configured to deliver a voltage to operate the MOS capacitor in an accumulation mode.

A MOS capacitor, a method of fabricating the same, and a semiconductor device using the same are provided. The MOS capacitor is arranged in an outermost cell block of the semiconductor device employing an open bit line structure. The MOS capacitor includes a first electrode arranged in a semiconductor substrate, a dielectric layer arranged on a semiconductor substrate, and a second electrode arranged on the dielectric layer and including a dummy bit line.

Described herein are IC devices that include semiconductor nanoribbons stacked over one another to realize high-density three-dimensional (3D) dynamic random-access memory (DRAM). An example device includes a first semiconductor nanoribbon, a second semiconductor nanoribbon, a first source or drain (S/D) region and a second S/D region in each of the first and second nanoribbons, a first gate stack at least partially surrounding a portion of the first nanoribbon between the first and second S/D regions in the first nanoribbon, and a second gate stack, not electrically coupled to the first gate stack, at least partially surrounding a portion of the second nanoribbon between the first and second S/D regions in the second nanoribbon. The device further includes a bitline coupled to the first S/D regions of both the first and second nanoribbons.

To increase a storage capacity of a memory module per unit area, and to provide a memory module with low power consumption, a transistor formed using an oxide semiconductor film, a silicon carbide film, a gallium nitride film, or the like, which is highly purified and has a wide band gap of 2.5 eV or higher is used for a DRAM, so that a retention period of potentials in a capacitor can be extended. Further, a memory cell has n capacitors with different capacitances and the n capacitors are each connected to a corresponding one of n data lines, so that a variety of the storage capacitances can be obtained and multilevel data can be stored. The capacitors may be stacked for reducing the area of the memory cell.

The present disclosure relates to a method for manufacturing pillar or hole structures in a layer of semiconductor device, and associated semiconductor structure. At least one embodiment relates to a method for manufacturing pillar structures in a layer of a semiconductor device. The pillar structures are arranged at positions forming a hexagonal matrix configuration. The method includes embedding alignment pillar structures in a backfill brush polymer layer. The method also includes providing a BCP layer on a substantially planar surface defined by an upper surface of the alignment pillar structures and the backfill brush polymer layer. Further, the method includes inducing polymer microphase separation of the BCP polymer layer into pillar structures of a first component of the BCP polymer layer embedded in a second component of the BCP polymer layer.

A method for forming a boron-doped silicon germanium film on a base film in a surface of an object to be processed includes: forming a seed layer by adsorbing a chlorine-free boron-containing gas to a surface of the base film; and forming a boron-doped silicon germanium film on the surface of the base film to which the seed layer is adsorbed by using a silicon raw material gas, a germanium raw material gas, and a boron doping gas through a chemical vapor deposition method.

A semiconductor manufacturing method includes: providing a semiconductor substrate, in which the semiconductor substrate includes an array region and a peripheral circuit region, in the array region, multiple capacitor contact holes are on the semiconductor substrate, and a first conductive layer is deposited on a bottom of each of the capacitor contact hole, and in the peripheral circuit region, a device layer is on the semiconductor substrate; treating the first conductive layer to increase its roughness; forming wire contact holes exposing the semiconductor substrate in the peripheral circuit region; forming a transition layer that at least covers a surface of the first conductive layer and a surface of the semiconductor substrate exposed by the wire contact holes; and forming a second conductive layer that covers the transition layer, and fills the capacitor contact holes and the wire contact holes.