A structure includes a semiconductor substrate, a gate structure, a source/drain feature, a source/drain contact, a dielectric layer, and a ferroelectric random access memory (FERAM) structure. The gate structure is on the semiconductor substrate. The source/drain feature is adjacent to the gate structure. The source/drain contact lands on the source/drain feature. The dielectric layer spans the source/drain contact. The FeRAM structure is partially embedded in the dielectric layer and includes a bottom electrode layer on the source/drain contact and having an U-shaped cross section, a ferroelectric layer conformally formed on the bottom electrode layer, and a top electrode layer over the ferroelectric layer.

Some embodiments include a NAND memory array having a vertical stack of alternating insulative levels and conductive levels. The conductive levels include control gate regions and include second regions proximate to the control gate regions. High-k dielectric structures are directly against the control gate regions and extend entirely across the insulative levels. Charge-blocking material is adjacent to the high-k dielectric structures. Charge-storage material is adjacent to the charge-blocking material. The charge-storage material is configured as segments which are vertically stacked one atop another, and which are vertically spaced from one another. Gate-dielectric material is adjacent to the charge-storage material. Channel material extends vertically along the stack and is adjacent to the gate-dielectric material. Some embodiments include integrated assemblies, and methods of forming integrated assemblies.

A device including a III-N material is described. The device includes a transistor structure having a first layer including a first group III-nitride (III-N) material, a polarization charge inducing layer above the first layer, the polarization charge inducing layer including a second III-N material, a gate electrode above the polarization charge inducing layer and a source structure and a drain structure on opposite sides of the gate electrode. The device further includes a plurality of peripheral structures adjacent to transistor structure, where each of the peripheral structure includes the first layer, but lacks the polarization charge inducing layer, an insulating layer above the peripheral structure and the transistor structure, wherein the insulating layer includes a first dielectric material. A metallization structure, above the peripheral structure, is coupled to the transistor structure.

Disclosed are semiconductor devices and methods of manufacturing the same. The semiconductor device comprises a gate electrode on a substrate, an upper capping pattern on the gate electrode, and a lower capping pattern between the gate electrode and the upper capping pattern. The lower capping pattern comprises a first portion between the gate electrode and the upper capping pattern, and a plurality of second portions extending from the first portion onto corresponding side surfaces of the upper capping pattern. The upper capping pattern covers a topmost surface of each of the second portions.

Some embodiments include an integrated assembly having first and second pillars of semiconductor material laterally offset from one another. The pillars have source/drain regions and channel regions vertically offset from the source/drain regions. Gating structures pass across the channel regions, and extend along a first direction. An insulative structure is over regions of the first and second pillars, and extends along a second direction which is crosses the first direction. Bottom electrodes are coupled with the source/drain regions. Leaker-device-structures extend upwardly from the bottom electrodes. Ferroelectric-insulative-material is laterally adjacent to the leaker-device-structures and over the regions of the bottom electrodes. Top-electrode-material is over the ferroelectric-insulative-material and is directly against the leaker-device-structures. Some embodiments include methods of forming integrated assemblies.

A semiconductor device includes a semiconductor layer extending in a first direction and including a source region and a drain region, which are apart from each other in the first direction; an insulating layer surrounding the semiconductor layer; a first gate electrode layer surrounding the insulating layer; a ferroelectric layer provided on the first gate electrode layer; and a second gate electrode layer provided on the ferroelectric layer.

Provided is a ferroelectric field effect transistor (FeFET) which has a wide memory window even if the ferroelectric film thickness is 200 nm or less, and which has excellent data retention characteristics, pulse rewriting endurance and the like. An FeFET which has a structure wherein an insulating body (11) and a gate electrode conductor (4) are sequentially laminated in this order on a semiconductor base (10) that has a source region (12) and a drain region (13). The insulating body (11) is configured by laminating a first insulating body (1) and a second insulating body (2) in this order on the base (10), and the second insulating body (2) is mainly composed of an oxide of strontium, calcium, bismuth and tantalum.

The disclosed subject matter provides a semiconductor structure and fabrication method thereof. In a semiconductor structure, a dielectric layer, a plurality of discrete gate structures, and a plurality of sidewall spacers are formed on a semiconductor substrate. The plurality of discrete gate structures and sidewall spacers are formed in the dielectric layer, and a sidewall spacer is formed on each side of each gate structure. A top portion of each gate structure and a top portion of the dielectric layer between neighboring sidewall spacers of neighboring gate structures are removed. A protective layer is formed on each of the remaining dielectric layer and the remaining gate structures. Contact holes are formed on the semiconductor substrate, between neighboring sidewall spacers, and on opposite sides of the protective layer on the remaining dielectric layer. A metal plug is formed in each contact hole.

A semiconductor device, including a substrate, a deposition layer deposited on the substrate, a semiconductor region selectively provided in the deposition layer, a semiconductor layer provided on the deposition layer and the semiconductor region, a first region and a second region selectively provided in the semiconductor layer, a gate electrode provided on the second region and the semiconductor layer via a gate insulating film, a source electrode in contact with the semiconductor layer and the second region, an interlayer insulating film covering the gate electrode, a drain electrode provided on the substrate, a plating film selectively provided on the source electrode at portions thereof on which the protective film is not provided, and a pin-shaped electrode connected to the plating film via solder. The second region is not formed directly beneath a portion where the plating film, the protective film and the source electrode are in contact with one another.

A semiconductor device, including a substrate, a deposition layer deposited on the substrate, a semiconductor region selectively provided in the deposition layer, a semiconductor layer provided on the deposition layer and the semiconductor region, a first region and a second region selectively provided in the semiconductor layer, a gate electrode provided on the second region and the semiconductor layer via a gate insulating film, a source electrode in contact with the semiconductor layer and the second region, an interlayer insulating film covering the gate electrode, a drain electrode provided on the substrate, a plating film selectively provided on the source electrode at portions thereof on which the protective film is not provided, and a pin-shaped electrode connected to the plating film via solder. The second region is not formed directly beneath a portion where the plating film, the protective film and the source electrode are in contact with one another.