Abstract: A semiconductor device includes a substrate, a semiconductor fin, gate spacers, a gate structure. The semiconductor fin is on the substrate. The gate spacers are over the semiconductor fin. The gate structure is on the semiconductor fin and between the gate spacers. The gate structure includes a gate dielectric layer and a first work function metal over the gate dielectric layer, in which a top surface of the first work function metal is lower than a top surface of the gate dielectric layer, and a distance between the top surface of the first work function metal and the top surface of the gate dielectric layer is less than about 1 nm.

Abstract: A semiconductor device includes a first dielectric layer, a gate electrode embedded within the first dielectric layer, a layer stack including a gate dielectric layer, a channel layer including a semiconducting metal oxide material, and a second dielectric layer, and a source electrode and a drain electrode embedded in the second dielectric layer and contacting a respective portion of a top surface of the channel layer. A combination of the gate electrode, the gate dielectric layer, the channel layer, the source electrode, and the drain electrode forms a transistor. The total length of the periphery of a bottom surface of the channel layer that overlies the gate electrode is equal to the width of the gate electrode or twice the width of the gate electrode, and resputtering of the gate electrode material on sidewalls of the channel layer is minimized.

Abstract: A device structure includes at least one selector device. Each selector device includes a vertical stack including, from bottom to top, a bottom electrode, a metal oxide semiconductor channel layer, and a top electrode and located over a substrate, a gate dielectric layer contacting sidewalls of the bottom electrode, the metal oxide semiconductor channel layer, and the top electrode, and a gate electrode formed within the gate dielectric layer and having a top surface that is coplanar with a top surface of the top electrode. Each top electrode or each bottom electrode of the at least one selector device may be contacted by a respective nonvolatile memory element to provide a one-selector one-resistor memory cell.

Abstract: A semiconductor device includes a substrate, a semiconductor fin protruding from the substrate, an isolation layer disposed above the substrate, a dielectric fin with a bottom portion embedded in the isolation layer, and a gate structure over top and sidewall surfaces of the semiconductor fin and the dielectric fin. The semiconductor fin has a first sidewall and a second sidewall facing away from the first sidewall. The isolation layer includes a first portion disposed on the first sidewall of the semiconductor fin and a second portion disposed on the second sidewall of the semiconductor fin. A top portion of the dielectric fin includes an air pocket with a top opening sealed by the gate structure.

Abstract: A memory device may include at least one multinary memory cell. Each multinary memory cell includes a parallel connection of N sub-bit units. N is an integer greater than 1. Each of the N sub-bit units includes a series connection of a respective transistor and a respective capacitor. A first sub-bit unit includes a first capacitor having a capacitance of C, and each i-th sub-unit includes an i-th capacitor having a capacitance of about 2i-1×C. A multinary bit having 2N values may be stored. A device network including multiple multinary logic units is also provided. Each of multiple multinary logic unit includes a parallel connection of N sub-bit units. Each sub-bit unit includes a series connection of a respective transistor and a respective capacitor having capacitance ratios of powers of 2.

Abstract: A device includes a resistance switching layer, a capping layer, a top electrode, a first spacer, and a second spacer. The resistance switching layer is over a substrate. The capping layer is over the resistance switching layer. The top electrode is over the capping layer. The first spacer lines the resistance switching layer and the capping layer. The second spacer lines the first spacer. The capping layer is in contact with the top electrode, the first spacer, and the second spacer.

Abstract: A memory device, a semiconductor device and manufacturing methods for forming the memory device and the semiconductor device are provided. The memory device include a stacking structure, a switching layer, channel layers and pairs of conductive pillars. The stacking structure includes alternately stacked isolation layers and word lines, and extends along a first direction. The stacking structure has a staircase portion and a connection portion at an edge region of the stacking structure. The connection portion extends along the staircase portion and located aside the staircase portion, and may not be shaped into a staircase structure. The switching layer covers a sidewall of the stacking structure. The channel layers cover a sidewall of the switching layer, and are laterally spaced apart from one another along the first direction. The pairs of conductive pillars stand on the substrate, and in lateral contact with the switching layer through the channel layers.

Abstract: A ferroelectric memory device, a manufacturing method of the ferroelectric memory device and a semiconductor chip are provided. The ferroelectric memory device includes a gate electrode, a ferroelectric layer, a channel layer, first and second blocking layers, and source/drain electrodes. The ferroelectric layer is disposed at a side of the gate electrode. The channel layer is capacitively coupled to the gate electrode through the ferroelectric layer. The first and second blocking layers are disposed between the ferroelectric layer and the channel layer. The second blocking layer is disposed between the first blocking layer and the channel layer. The first and second blocking layers comprise a same material, and the second blocking layer is further incorporated with nitrogen. The source/drain electrodes are disposed at opposite sides of the gate electrode, and electrically connected to the channel layer.

Abstract: A semiconductor device is described. The semiconductor device includes a substrate and a metal layer disposed on the substrate. A seed layer is formed on the metal layer. A ferroelectric gate layer is formed on the seed layer. A channel layer is formed over the ferroelectric gate layer. The seed layer is arranged to increase the orthorhombic phase fraction of the ferroelectric gate layer.

Abstract: A device includes a first semiconductor structure, a second semiconductor structure, and an isolation structure which is disposed between the first and second semiconductor structures, and which includes a dielectric material having a dielectric constant higher than 8 and lower than 16. A method for manufacturing the device is also disclosed.

Abstract: A method for manufacturing a memory device includes forming a first metal layer over a substrate, forming a magnetic tunnel junction (MTJ) layer stack over the first metal layer, forming a second metal layer over the MTJ layer stack, forming a hard mask layer over the second metal layer, performing a first etching process on the MTJ layer stack to form an MTJ structure and a redeposited layer on a sidewall of the MTJ structure, performing a second etching process to remove the redeposited layer, and performing a third etching process on the sidewall of the MTJ structure.

Abstract: Various embodiments of the present disclosure are directed towards an integrated chip (IC) comprising a first electrode structure disposed in a substrate. A first ferroelectric structure is disposed on a first side of the first electrode structure. A channel structure is disposed on a first side of the first ferroelectric structure. The channel structure includes a plurality of individual channel structures and a plurality of insulator structures. The plurality of individual channel structures and the plurality of insulator structures are alternately stacked. A pair of source/drain (S/D) structures are disposed on the first side of the first ferroelectric structure. The pair of S/D structures extend vertically through the channel structure, and the first electrode structure is disposed laterally between the S/D structures of the pair of S/D structures.

Abstract: A semiconductor device includes a substrate, a gate electrode, a gate dielectric layer, a channel layer, a source electrode and a drain electrode. The gate electrode is disposed over the substrate. The gate dielectric layer is disposed over the gate electrode. The channel layer is disposed over the gate dielectric layer. The source electrode and the drain electrode are disposed over the channel layer and beside the gate electrode. In some embodiments, each of the source electrode and the drain electrode includes a glue layer and a metal pattern, and a thickness of the glue layer adjacent to a sidewall of the metal pattern is greater than a thickness of the glue layer adjacent to a bottom of the metal pattern.

Abstract: In a method of manufacturing a semiconductor device, an underlying structure is formed over a substrate. A film is formed over the underlying structure. Surface topography of the film is measured and the surface topography is stored as topography data. A local etching is performed by using directional etching and scanning the substrate so that an entire surface of the film is subjected to the directional etching. A plasma beam intensity of the directional etching is adjusted according to the topography data.

Abstract: A method includes forming a gate stack over a semiconductor region, and forming a first gate spacer on a sidewall of the gate stack. The first gate spacer includes an inner sidewall spacer, and a dummy spacer portion on an outer side of the inner sidewall spacer. The method further includes removing the dummy spacer portion to form a trench, and forming a dielectric layer to seal a portion of the trench as an air gap. The air gap and the inner sidewall spacer in combination form a second gate spacer. A source/drain region is formed to have a portion on an outer side of the second gate spacer.

Abstract: In some embodiments, the present disclosure relates to an integrated chip that includes a gate electrode over a substrate, and a gate dielectric layer arranged over the gate electrode. The gate dielectric layer includes a ferroelectric material. An active structure is arranged over the gate dielectric layer and includes a semiconductor material. A source contact and a drain contact are arranged over the active structure. A capping structure is arranged between the source and drain contacts and over the active structure. The capping structure includes a first metal material.

Abstract: A semiconductor device and method of forming thereof that includes a transistor of a peripheral circuit on a substrate. A first interconnect structure such as a first access line is formed over the transistor. A via extends above the first access line. A plurality of memory cell structures is formed over the interconnect structure and the via. A second interconnect structure, such as a second access line, is formed over the memory cell structure. The first access line is coupled to a first memory cell of the plurality of memory cell structures and second access line is coupled to a second memory cell of the plurality of memory cell structures.

Abstract: A method for manufacturing a semiconductor feature includes: alternatingly forming first and second dielectric layers on a semiconductor substrate along a vertical direction; forming multiple spaced-apart trenches penetrating the first and second dielectric layers; forming multiple support segments filling the trenches; removing the second dielectric layers to form multiple spaces; forming multiple conductive layers filling the spaces; removing the support segments to expose the conductive layers and the first dielectric layers; selectively forming a blocking layer covering the first dielectric layers outside of the conductive layers; forming multiple selectively-deposited sub-layers on the exposed conductive layers outside of the blocking layer and each connected to one of the conductive layers; forming multiple channel sub-layers on the selectively-deposited sub-layers outside of the blocking layer; removing the blocking layer; forming multiple isolation sub-layers filling the trenches; and forming multiple