Abstract: An integrated circuit includes laterally adjacent first and second devices. The first device includes (i) first source and drain regions, (ii) a first body including semiconductor material laterally extending between the first source and drain regions, (iii) a first sub-fin below the first body, and (iv) a first gate structure on the first body. The second device includes (i) second source and drain regions, (ii) a second body including semiconductor material laterally extending from the second source and drain regions, (iii) a second sub-fin below the second body, and (iv) a second gate structure on the second body. A second dielectric material is laterally between the first and second sub-fins. A third dielectric material is laterally between the first and second sub-fins, and above the second dielectric material. A gate cut including first dielectric material is laterally between the first and second gate structures, and above the third dielectric material.

Abstract: An integrated circuit structure includes a first interconnect layer, and a second interconnect layer above the first interconnect layer. The first interconnect layer includes a first interconnect feature and a second interconnect feature. The second interconnect layer includes a third interconnect feature, a fourth interconnect feature, and a fifth interconnection feature. The third interconnect feature extends from an upper surface of the first interconnect feature to an upper surface of the second interconnect layer. In an example, the fourth interconnect feature extends from an upper surface of the second interconnect feature to below the upper surface of the second interconnect layer, and the fifth interconnect feature extends from an upper surface of the fourth interconnect feature to the upper surface of the second interconnect layer. Thus, a double-decked vertical stack of interconnect features is formed using the fourth interconnect feature within the second interconnect layer.

Abstract: Techniques are provided herein for forming transistor devices with reduced parasitic capacitance, such as transistors used in a memory structure. In an example, a given memory structure includes memory cells, with a given memory cell having an access device and a storage device. The access device may include, for example, a thin film transistor (TFT), and the storage device may include a capacitor. Any of the given TFTs may include a dielectric liner extending along sidewalls of the TFT. The TFT includes a recess (e.g., a dimple) that extends laterally inwards toward a midpoint of a semiconductor region of the TFT. The dielectric liner thus also pinches or otherwise extends inward. This pinched-in dielectric liner may reduce parasitic capacitance between the contacts of the TFT and the gate electrode of the TFT. The pinched-in dielectric liner may also protect the contacts from forming too deep into the semiconductor region.

Abstract: Techniques are provided herein to form semiconductor devices that use uniform topside dielectric plugs as masking structures to form conductive contacts to various source or drain regions. In an example, a plurality of semiconductor devices each include one or more semiconductor regions extending in a first direction between corresponding source or drain regions. The source or drain regions are adjacent to one another along a second direction different from the first direction. Conductive contacts are formed over the source or drain regions of the semiconductor devices. A dielectric fill is between one or more adjacent pairs of conductive contacts and dielectric masking structures having a substantially uniform thickness are present over the dielectric fill between adjacent pairs of conductive contacts. This uniform thickness characteristic applies to all of the masking structures regardless of their length along the second direction.