Abstract: Integrated circuit structures having differentiated interconnect lines in a same dielectric layer, and methods of fabricating integrated circuit structures having differentiated interconnect lines in a same dielectric layer, are described. In an example, an integrated circuit structure includes an inter-layer dielectric (ILD) layer above a substrate. A plurality of conductive interconnect lines is in the ILD layer. The plurality of conductive interconnect lines includes a first interconnect line having a first height, and a second interconnect line immediately laterally adjacent to but spaced apart from the first interconnect line, the second interconnect line having a second height less than the first height.

Abstract: Embodiments herein describe techniques for a semiconductor device including a substrate, a first inter-level dielectric (ILD) layer above the substrate, and a second ILD layer above the first ILD layer. The semiconductor device further includes a capacitor having a bottom plate above the substrate, a capacitor dielectric layer adjacent to and above the bottom plate, and a top plate adjacent to and above the capacitor dielectric layer. The bottom plate, the capacitor dielectric layer, and the top plate are within the first ILD layer or the second ILD layer. Furthermore, an air gap is formed next to the top plate and below a top surface of the second ILD layer. Other embodiments may be described and/or claimed.

Abstract: Embodiments herein describe techniques for a semiconductor device including a substrate, a first inter-level dielectric (ILD) layer above the substrate, and a second ILD layer above the first ILD layer. A first capacitor and a second capacitor are formed within the first ILD layer and the second ILD layer. A first top plate of the first capacitor and a second top plate of the second capacitor are formed at a boundary between the first ILD layer and the second ILD layer. The first capacitor and the second capacitor are separated by a dielectric area in the first ILD layer. The dielectric area includes a first dielectric area that is coplanar with the first top plate or the second top plate, and a second dielectric area above the first dielectric area and to separate the first top plate and the second top plate. Other embodiments may be described and/or claimed.

Abstract: Embodiments herein describe techniques for a semiconductor device including a substrate. A first capacitor includes a first top plate and a first bottom plate above the substrate. The first top plate is coupled to a first metal electrode within an inter-level dielectric (ILD) layer to access the first capacitor. A second capacitor includes a second top plate and a second bottom plate, where the second top plate is coupled to a second metal electrode within the ILD layer to access the second capacitor. The second metal electrode is disjoint from the first metal electrode. The first capacitor is accessed through the first metal electrode without accessing the second capacitor through the second metal electrode. Other embodiments may be described and/or claimed.

Abstract: Embodiments herein describe techniques for a semiconductor device having an interconnect structure including an inter-level dielectric (ILD) layer between a first layer and a second layer of the interconnect structure. The interconnect structure further includes a separation layer within the ILD layer. The ILD layer includes a first area with a first height to extend from a first surface of the ILD layer to a second surface of the ILD layer. The ILD layer further includes a second area with a second height to extend from the first surface of the ILD layer to a surface of the separation layer, where the first height is larger than the second height. Other embodiments may be described and/or claimed.

Abstract: An integrated circuit structure comprises one or more backend-of-line (BEOL) interconnects formed over a first ILD layer. An etch stop layer is over the one or more BEOL interconnects, the etch stop layer having a plurality of vias that are in contact with the one or more BEOL interconnects. An array of BEOL thin-film-transistors (TFTs) is over the etch stop layer, wherein adjacent ones of the BEOL TFTs are separated by isolation trench regions. The TFTs are aligned with at least one of the plurality of vias to connect to the one or more BEOL interconnects, wherein each of the BEOL TFTs comprise a bottom gate electrode, a gate dielectric layer over the bottom gate electrode, and an oxide-based semiconductor channel layer over the bottom gate electrode having source and drain regions therein. Contacts are formed over the source and drain regions of each of BEOL TFTs, wherein the contacts have a critical dimension of 35 nm or less, and wherein the BEOL TFTs have an absence of diluted hydro-fluoride (DHF).

Abstract: Described herein are embedded dynamic random-access memory (eDRAM) memory cells and arrays, as well as corresponding methods and devices. An exemplary eDRAM memory array implements a memory cell that uses a thin-film transistor (TFT) as a selector transistor. One source/drain (S/D) electrode of the TFT is coupled to a capacitor for storing a memory state of the cell, while the other S/D electrode is coupled to a bitline. The bitline may be a shallow bitline in that a thickness of the bitline may be smaller than a thickness of one or more metal interconnects provided in the same metal layer as the bitline but used for providing electrical connectivity for components outside of the memory array. Such a bitline may be formed in a separate process than said one or more metal interconnects. In an embodiment, the memory cells may be formed in a back end of line process.

Abstract: An integrated circuit includes a base, a first transistor structure on or above the base, and a second transistor structure on or above the base, where the second transistor structure is spaced from the first transistor structure. An insulator material at least partially encapsulates an airgap or other gas pocket laterally between the first transistor structure and the second transistor structure. The gas pocket is at least 5 nm in height and at least 5 nm wide according to an embodiment, and in some cases is as tall or taller than active device layers of the transistor structures it separates.

Abstract: A scattered light point spread function is measured for use in fabricating microelectronic and micromechanical devices using photolithography. In one example, a photosensitive layer of a microelectronic substrate is exposed through a test mask, the test mask having a series of differently sized patterns, each pattern surrounding a central monitor feature, the differently sized patterns each being evenly distributed about its respective central monitor feature. An indication of the exposure of the photosensitive layer is measured for a plurality of the series of differently sized patterns. The exposure indication is compared to the pattern size. The comparison is fitted to a function and the function is applied in correcting photolithography mask layouts.

Abstract: Some embodiments of the present invention include apparatuses and methods relating to improved substrate patterning for multi-gate transistors.

Abstract: A multi-layer alternating phase shift mask and associated techniques are generally described. In one example, a photomask includes a glass substrate, a compensating layer of material coupled with the glass substrate, the material having optical properties to compensate for thick mask effects, an absorber layer coupled with the compensating layer, the absorber layer having a first opening patterned therein, and the absorber layer and the compensating layer having a second opening patterned therein, the second opening having a depth selected to provide a desired phase shift, the compensating material having an index of refraction that is greater than the index of refraction of the glass substrate to reduce the depth of the second opening to provide a desired phase shift.

Abstract: A scattered light point spread function is measured for use in fabricating microelectronic and micromechanical devices using photolithography. In one example, a photosensitive layer of a microelectronic substrate is exposed through a test mask, the test mask having a series of differently sized patterns, each pattern surrounding a central monitor feature, the differently sized patterns each being evenly distributed about its respective central monitor feature. An indication of the exposure of the photosensitive layer is measured for a plurality of the series of differently sized patterns. The exposure indication is compared to the pattern size. The comparison is fitted to a function and the function is applied in correcting photolithography mask layouts.