Occurrence of short-channel characteristics and parasitic capacitance of a MOSFET on a SOI substrate is prevented. A sidewall having a stacked structure obtained by sequentially stacking a silicon oxide film and a nitride film is formed on a side wall of a gate electrode on the SOI substrate. Subsequently, after an epitaxial layer is formed beside the gate electrode, and then, the nitride film is removed. Then, an impurity is implanted into an upper surface of the semiconductor substrate with using the gate electrode and the epitaxial layer as a mask, so that a halo region is formed in only a region of the upper surface of the semiconductor substrate which is right below a vicinity of both ends of the gate electrode.

Occurrence of short-channel characteristics and parasitic capacitance of a MOSFET on a SOI substrate is prevented. A sidewall having a stacked structure obtained by sequentially stacking a silicon oxide film and a nitride film is formed on a side wall of a gate electrode on the SOI substrate. Subsequently, after an epitaxial layer is formed beside the gate electrode, and then, the nitride film is removed. Then, an impurity is implanted into an upper surface of the semiconductor substrate with using the gate electrode and the epitaxial layer as a mask, so that a halo region is formed in only a region of the upper surface of the semiconductor substrate which is right below a vicinity of both ends of the gate electrode.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a substrate including a dense area and an open area; a dielectric structure positioned on the substrate; a landing pad positioned in the dielectric structure and above the dense area; a first contact positioned on the landing pad and in the dielectric structure; and a second contact positioned in the dielectric structure and on the open area of the substrate. A top surface of the first contact and a top surface of the second contact are substantially coplanar. A width of the first contact is less than the one half of a width of the second contact.

A construction of integrated circuitry comprises a trench isolation region in semiconductive material. The trench isolation region comprises laterally-opposing laterally-outermost first regions which comprise a first material and a second region laterally-inward of the first regions. The second region comprises a second material of different composition from that of the first material. A diffusion region is in the uppermost portion of the semiconductive material directly against a sidewall of one of the first regions. Insulator material is above the trench isolation region and the diffusion region. An elevationally-elongated conductive via is in the insulator material and extends to the diffusion region and the trench isolation region. The conductive via laterally overlaps the diffusion region and the one first region. The conductive via is directly against a top surface of the diffusion region, is directly against an upper portion of a sidewall of the diffusion region, and is directly against a laterally-outer sidewall of the second material of the second region of the trench isolation material. Other embodiments, including method, are disclosed.

A high voltage device includes: a semiconductor layer, a well, a body region, a body contact, a gate, a source, and a drain. The body cofntact is configured as an electrical contact of the body region. The body contact and the source overlap with each other to define an overlap region. The body contact has a depth from an upper surface of the semiconductor layer, wherein the depth is deeper than a depth of the source, whereby a part of the body contact is located vertically below the overlap region. A length of the overlap region in a channel direction is not shorter than a predetermined length, so as to suppress a parasitic bipolar junction transistor from being turning on when the high voltage device operates, wherein the parasitic bipolar junction transistor is formed by a part of the well, a part of the body region and a part of the source.

A 3D semiconductor device with a built-in-test-circuit (BIST), the device comprising: a first single-crystal substrate with a plurality of logic circuits disposed therein, wherein said first single-crystal substrate comprises a device area, wherein said plurality of logic circuits comprise at least a first interconnected array of processor logic, wherein said plurality of logic circuits comprise at least a second interconnected set of circuits comprising a first logic circuit, a second logic circuit, and a third logic circuit, wherein said second interconnected set of logic circuits further comprise switching circuits that support replacing said first logic circuit and/or said second logic circuit with said third logic circuit; and said built-in-test-circuit (BIST), wherein said first logic circuit is testable by said built-in-test-circuit (BIST), and wherein said second logic circuit is testable by said built-in-test-circuit (BIST).

Embodiments disclosed herein describe a semiconductor structure. The semiconductor structure may include a device region with a first source/drain (S/D) and a second S/D. The semiconductor structure may also include a buried power rail (BPR) under the device region. A critical dimension of the BPR may be larger than a distance between the first S/D and the second S/D. The semiconductor structure may also include a via-contact-to-buried power rail (VBPR) between the BPR and the S/D.

A semiconductor device is provided. The semiconductor device includes a protective liner, and a buried power rail on a first portion of the protective liner, wherein the protective liner is on opposite sides of the buried power rail. The semiconductor device further includes a source/drain on a second portion of the protective liner, wherein the source/drain is offset from the buried power rail, and a source/drain contact on the source/drain and in electrical communication with the buried power rail.

A 3D device includes a first level including a first single crystal layer with control circuitry, where the control circuitry includes first single crystal transistors; a first metal layer atop first single crystal layer; a second metal layer atop the first metal layer; a third metal layer atop the second metal layer; second level (includes a plurality of second transistors) atop the third metal layer; a fourth metal layer disposed above the one second level; a fifth metal layer atop the fourth metal layer, where the second level includes at least one first oxide layer overlaid by a transistor layer and then overlaid by a second oxide layer; a global power distribution grid, which includes the fifth metal layer; a local power distribution grid, which includes the second metal layer, the thickness of the fifth metal layer is at least 50% greater than the thickness of the second metal layer.

In vertically stacked device structures, a buried interconnect and bottom contacts can be formed, thereby allowing connections to be made to device terminals from both below and above the stacked device structures. Techniques herein include a structure that enables electrical access to each independent device terminal of multiple devices, stacked on top of each other, without interfering with other devices and the local connections that are needed.