A semiconductor structure including one or more semiconductor devices on a wafer. The one or more devices having source/drain junctions. The semiconductor structure further includes a recessed middle-of-line (MOL) oxide layer, and an air-gap oxide layer including one or more introduced air-gaps. The air-gap oxide layer is positioned over the one or more semiconductor devices and the MOL oxide layer. A nitride layer is positioned over the one or more semiconductor devices. Trenches are formed through the nitride layer down to the source/drain junctions. A silicide fills the trenches.

A method of fabricating a semiconductor device includes forming a hard mask layer over a substrate. A multi-layer resist is formed over the hard mask layer. The multi-layer resist is etched to form a plurality of openings in the multi-layer resist to expose a portion of the hard mask layer. Ion are directionally provided at an angle to the multi-layer resist to predominately contact sidewalls of the plurality of openings in the multi-layer resist rather than the hard mask layer. In one embodiment, the multi-layer resist is directionally etched by directing etch ions at an angle to predominately contact sidewalls of the plurality of openings in the multi-layer resist rather than the hard mask layer. In another embodiment, the multi-layer resist is directionally implanted by directing implant ions at an angle to predominately contact sidewalls of the plurality of openings in the multi-layer resist rather than the hard mask layer.

Integrated circuit devices include trenches in a material layer that divide the material layer into fins. With such devices, an insulator partially fills the trenches and contacts the material layer. The top surface of the insulator (e.g., the surface opposite where the insulator contacts the material layer) has a convex dome shape between at least two of the fins. The dome shape has a first thickness from (from the bottom of the trench) where the insulator contacts the fins, and a second thickness that is greater than the first thickness where the insulator is between the fins. Further, there is a maximum thickness difference between the first and second thicknesses at the midpoint between the fins (e.g., the highest point of the dome shape is at the midpoint between the fins). Also, the top surface of the first insulator has concave divots where the first insulator contacts the fins.

A method includes providing a structure having a substrate and first and second fins over the substrate and oriented lengthwise generally along a first direction; epitaxially growing semiconductor source/drain (S/D) features over the first and second fins, wherein a first semiconductor S/D feature over the first fin merges with a second semiconductor S/D feature over the second fin; and performing a first etching process to an area between the first and second fins, wherein the first etching process separates the first and second semiconductor S/D features.

A method of forming a vertical fin field effect transistor (vertical finFET) with a self-aligned shallow trench isolation region, including forming a pinch-off layer on one or more vertical fin segments, wherein the pinch-off layer has a thickness on the sidewalls of the one or more vertical fin segments, forming a trench mask layer on predetermined portions of the pinch-off layer, removing portions of the pinch-off layer not covered by the trench mask layer, where the removed portions of the pinch-off layer exposes underlying portions of the substrate, and removing at least a portion of the substrate to form one or more isolation region trenches, where the distance of the sidewall of one of the one or more isolation region trenches to an adjacent vertical fin segment is determined by the thickness of the pinch-off layer.

A method includes providing a structure having a substrate and first and second fins over the substrate and oriented lengthwise generally along a first direction; epitaxially growing semiconductor source/drain (S/D) features over the first and second fins, wherein a first semiconductor S/D feature over the first fin merges with a second semiconductor S/D feature over the second fin; and performing a first etching process to an area between the first and second fins, wherein the first etching process separates the first and second semiconductor S/D features.

The present disclosure relates to a double-sided integrated circuit (IC) module, which includes an exposed semiconductor die on a bottom side. A double-sided IC module includes a module substrate with a top side and a bottom side. Electronic components are mounted to each of the top side and the bottom side. Generally, the electronic components are encapsulated by a mold compound. In an exemplary aspect, a portion of the mold compound on the bottom side of the module substrate is removed, exposing a semiconductor die surface of at least one of the electronic components.

The present invention relates to a composition for etching, comprising a first inorganic acid, a first additive represented by Chemical Formula 1, and a solvent. The composition for etching is a high-selectivity composition that can selectively remove a nitride film while minimizing the etch rate of an oxide film, and which does not have problems such as particle generation, which adversely affect the device characteristics.

A semiconductor device including a substrate, a capacitor, a stop layer, a first contact, and a second contact is provided. The substrate includes a memory array region and a peripheral circuit region. The capacitor is located in the memory array region. The capacitor includes a first electrode, a second electrode, and an insulating layer. The second electrode is located on the first electrode. The insulating layer is located between the first electrode and the second electrode. The stop layer is located on the second electrode in the memory array region and extends into the peripheral circuit region. A material of the stop layer is not a conductive material. The first contact is located in the memory array region, passes through the stop layer, and is electrically connected to the second electrode. The second contact is located in the peripheral circuit region and passes through the stop layer.

A method of forming a semiconductor structure includes forming a middle-of-line (MOL) oxide layer in the semiconductor structure. The MOL oxide layer including multiple gate stacks formed on a substrate. A nitride layer is formed over a silicide in the MOL oxide layer. At least one self-aligned contact area (CA) element is formed within the nitride layer. The MOL oxide layer is selectively recessed on a first side and a second side of the at least one self-aligned CA element leaving remaining portions of the MOL oxide layer on the nitride layer and a nitride. A nitride cap of the plurality of gate stacks is selectively recessed. An air-gap oxide layer is deposited for introducing one or more air-gaps in the deposited air-gap oxide layer. The air gap oxide layer is reduced to the at least one self-aligned CA element and the nitride layer.