Abstract: A method for fabricating a semiconductor device includes forming a first encapsulation layer along the device, including forming the first encapsulation layer along a memory device region associated with a memory device, forming an intermediate layer on the first encapsulation layer to enable etch endpoint detection and endpoint-based process control for encapsulation layer etch back, and forming a second encapsulation layer on the intermediate layer.

Abstract: Techniques to improve CD width and depth uniformity between features with different layout densities are provided. In one aspect, a method of forming a contact structure includes: patterning features in different regions of a dielectric at different layout densities whereby, due to etch loading effects, the features are patterned to different depths in the dielectric and have different bottom dimensions; depositing a sacrificial spacer into/lining the features whereby some of the features are pinched-off by the sacrificial spacer; opening up the sacrificial spacer at bottoms of one or more of the features that are not pinched-off by the sacrificial spacer; selectively extending the one or more features in the dielectric, such that the one or more features have a discontinuous taper with a stepped sidewall profile; removing the sacrificial spacer; and filling the features with a conductive material to form the contact structure. A contact structure is also provided.

Abstract: Techniques to improve CD width and depth uniformity between features with different layout densities are provided. In one aspect, a method of forming a contact structure includes: patterning features in different regions of a dielectric at different layout densities whereby, due to etch loading effects, the features are patterned to different depths in the dielectric and have different bottom dimensions; depositing a sacrificial spacer into/lining the features whereby some of the features are pinched-off by the sacrificial spacer; opening up the sacrificial spacer at bottoms of one or more of the features that are not pinched-off by the sacrificial spacer; selectively extending the one or more features in the dielectric, such that the one or more features have a discontinuous taper with a stepped sidewall profile; removing the sacrificial spacer; and filling the features with a conductive material to form the contact structure. A contact structure is also provided.

Abstract: A method for fabricating a semiconductor device includes forming one or more encapsulation spacers each about respective ones of one more memory pillar elements to have a geometry, including forming each encapsulation spacer to have a footing of at least about twice a critical dimension of its corresponding pillar, and depositing dielectric material on the one or more memory pillar elements and the one or more encapsulation spacers to form an interlayer dielectric free of voids based on the geometry.

Abstract: Embodiments of systems and methods for patterning features in tantalum nitride (TaN) are described. In an embodiment, a method may include receiving a substrate comprising a TaN layer. The method may also include etching the substrate to expose at least a portion of the TaN layer. Additionally, the method may include performing a passivation process to reduce lateral etching of the TaN layer. The method may further include etching the TaN layer to form a feature therein, wherein the passivation process is controlled to meet one or more target passivation objectives.

Abstract: A method for fabricating a semiconductor device includes forming one or more encapsulation spacers each about respective ones of one more memory pillar elements to have a geometry, including forming each encapsulation spacer to have a footing of at least about twice a critical dimension of its corresponding pillar, and depositing dielectric material on the one or more memory pillar elements and the one or more encapsulation spacers to form an interlayer dielectric free of voids based on the geometry.

Abstract: Apparatus and methods for dielectric gap fill evaluations are provided. In one example, a method can comprise providing a gap fill substrate over one or more interlayer dielectric trenches of a dielectric layer and over a first material located in the one or more interlayer dielectric trenches. The method can also comprise depositing a gap fill candidate material within one or more gap fill substrate trenches of the gap fill substrate. Furthermore, the method can comprise etching the gap fill candidate material until a void within the first material is identified. Additionally, the method can comprise filling the one or more gap fill substrate trenches with a second material to form one or more contacts with the first material to measure a leakage current of one or more pitches.

Abstract: A method for fabricating a semiconductor device includes forming a first encapsulation layer along the device, including forming the first encapsulation layer along a memory device region associated with a memory device, forming an intermediate layer on the first encapsulation layer to enable etch endpoint detection and endpoint-based process control for encapsulation layer etch back, and forming a second encapsulation layer on the intermediate layer.

Abstract: Apparatus and methods for dielectric gap fill evaluations are provided. In one example, a method can comprise providing a gap fill substrate over one or more interlayer dielectric trenches of a dielectric layer and over a first material located in the one or more interlayer dielectric trenches. The method can also comprise depositing a gap fill candidate material within one or more gap fill substrate trenches of the gap fill substrate. Furthermore, the method can comprise etching the gap fill candidate material until a void within the first material is identified. Additionally, the method can comprise filling the one or more gap fill substrate trenches with a second material to form one or more contacts with the first material to measure a leakage current of one or more pitches.

Abstract: Apparatus and methods for dielectric gap fill evaluations are provided. In one example, a method can comprise providing a gap fill substrate over one or more interlayer dielectric trenches of a dielectric layer and over a first material located in the one or more interlayer dielectric trenches. The method can also comprise depositing a gap fill candidate material within one or more gap fill substrate trenches of the gap fill substrate. Furthermore, the method can comprise etching the gap fill candidate material until a void within the first material is identified. Additionally, the method can comprise filling the one or more gap fill substrate trenches with a second material to form one or more contacts with the first material to measure a leakage current of one or more pitches.

Abstract: Apparatus and methods for dielectric gap fill evaluations are provided. In one example, a method can comprise providing a gap fill substrate over one or more interlayer dielectric trenches of a dielectric layer and over a first material located in the one or more interlayer dielectric trenches. The method can also comprise depositing a gap fill candidate material within one or more gap fill substrate trenches of the gap fill substrate. Furthermore, the method can comprise etching the gap fill candidate material until a void within the first material is identified. Additionally, the method can comprise filling the one or more gap fill substrate trenches with a second material to form one or more contacts with the first material to measure a leakage current of one or more pitches.

Abstract: Embodiments of systems and methods for patterning features in tantalum nitride (TaN) are described. In an embodiment, a method may include receiving a substrate comprising a TaN layer. The method may also include etching the substrate to expose at least a portion of the TaN layer. Additionally, the method may include performing a passivation process to reduce lateral etching of the TaN layer. The method may further include etching the TaN layer to form a feature therein, wherein the passivation process is controlled to meet one or more target passivation objectives.