An integrated circuit die includes a FinFET transistor. The FinFET transistor includes an anti-punch through region below a channel region. Undesirable dopants are removed from the anti-punch through region during formation of the source and drain regions. When source and drain recesses are formed, a layer of dielectric material is deposited in the recesses. An annealing process is then performed. Undesirable dopants diffuse from the anti-punch through region into the layer of dielectric material during the annealing process. The layer of dielectric material is then removed. The source and drain regions are then formed by depositing semiconductor material in the recesses.

A semiconductor device, the device including: a plurality of transistors, where at least one of the plurality of transistors includes a first single crystal source, channel, and drain, where at least one of the plurality of transistors includes a second single crystal source, channel, and drain, where the second single crystal source, channel, and drain is disposed above the first single crystal source, channel, and drain, where at least one of the plurality of transistors includes a third single crystal source, channel, and drain, where the third single crystal source, channel, and drain is disposed above the second single crystal source, channel, and drain, where at least one of the plurality of transistors includes a fourth single crystal source, channel, and drain, and where the first single crystal source or drain, and the second single crystal source or drain each include n+ doped regions.

Semiconductor devices having increased capacitance without increased fin height or increased chip area are disclosed. Grooves are formed across a width of the fin(s) to increase the overlapping surface area with the gate terminal, in particular with a length of the groove being less than or equal to the fin width. Methods of forming such grooved fins and semiconductor capacitor devices are also described.

A semiconductor device includes a fin structure, a two-dimensional (2D) material channel layer, a ferroelectric layer, and a metal layer. The fin structure extends from a substrate. The 2D material channel layer wraps around at least three sides of the fin structure. The ferroelectric layer wraps around at least three sides of the 2D material channel layer. The metal layer wraps around at least three sides of the ferroelectric layer.

The invention relates to a DRAM structure which comprise a capacitor set and at least a transistor. The capacitor set includes a first capacitor with a first electrode and a second capacitor with a second electrode, and a counter electrode is shared by the first and the second capacitors. The counter electrode is perpendicular or substantially perpendicular to an extension direction of an active region of the transistor, or the counter electrode is not positioned above or below the first and second electrode.

A memory structure and formation method are provided. The memory structure can comprise two second grooves along the row direction in each active area. The two second grooves divides each active area into a drain and two sources located on both sides of the drain. The surface of the insulating layer is lower than bottom surface of the second groove. A third groove is formed on the insulating layer between the first anti-etching dielectric layer and the second anti-etching dielectric layer to expose at least part of the surface of the sidewalls on both sides of the active area at the bottom of the second grooves and part of the surface of the sidewalls of the source and drain on both sides of the second grooves. The third groove is in connection with the second groove. A gate structure is formed in the second groove and the third groove.

A method for producing a 3D memory device, the method including: providing a first level including a single crystal layer and first alignment marks; forming memory control circuits including first single crystal transistors, where the first single crystal transistors include portions of the single crystal layer; forming at least one second level above the first level; performing a first etch step including etching lithography windows within the at least one second level; performing a first lithographic step over the at least one second level aligned to the first alignment marks; and performing additional processing steps to form a plurality of first memory cells within the at last one second level, where each of the plurality of first memory cells include one of a plurality of second transistors, and where the plurality of second transistors are aligned to the first alignment marks with a less than 40 nm alignment error.

Semiconductor devices having necked semiconductor bodies and methods of forming semiconductor bodies of varying width are described. For example, a semiconductor device includes a semiconductor body disposed above a substrate. A gate electrode stack is disposed over a portion of the semiconductor body to define a channel region in the semiconductor body under the gate electrode stack. Source and drain regions are defined in the semiconductor body on either side of the gate electrode stack. Sidewall spacers are disposed adjacent to the gate electrode stack and over only a portion of the source and drain regions. The portion of the source and drain regions under the sidewall spacers has a height and a width greater than a height and a width of the channel region of the semiconductor body.

A method of making a semiconductor device includes forming a first transistor on a substrate, wherein forming the first transistor comprises forming a first source/drain electrode in the substrate. The method further includes forming a second transistor on the substrate, wherein forming the second transistor comprises forming a second source/drain electrode. The method further includes forming an insulating layer extending into the substrate, wherein the insulating layer directly contacts the first source/drain electrode and the second source/drain electrode, a top surface of the insulating layer is above a top surface of the substrate.

A method for fabricating floating body memory cells (FBCs), and the resultant FBCs where gates favoring different conductivity type regions are used is described. In one embodiment, a p type back gate with a thicker insulation is used with a thinner insulated n type front gate. Processing, which compensates for misalignment, which allows the different oxide and gate materials to be fabricated is described.