Abstract: Semiconductor devices and methods of forming the same include forming a wet-strippable hardmask over semiconductor fins. The wet-strippable hardmask is anisotropically etched away in a first device region. At least one semiconductor fin is doped in the first device region. The wet-strippable hardmask is isotropically etched away in a second device region. Semiconductor devices are formed from the fins in the first and second device regions.

Abstract: The present disclosure relates to methods and apparatuses related to the deposition of a protective layer selective to an interlayer dielectric layer so that the protective layer is formed onto a top portion associated with the interlayer dielectric layer. In some embodiments, a method comprises: forming an interlayer dielectric layer on a substrate; covering a trench region with a metal liner, wherein the trench region is situated above the substrate and formed within the interlayer dielectric layer; and depositing a protective layer selective to the interlayer dielectric layer so that the protective layer is formed onto a top portion associated with the interlayer dielectric layer. In various embodiments, the depositing the protective layer comprises: repeatedly depositing the protective layer via a multi-deposition sequence; or depositing a self-assembled monolayer onto the top portion.

Abstract: A lithographic patterning method includes forming a multi-layer patterning material film stack on a semiconductor substrate. Forming the patterning material film stack more particularly includes forming a hard mask layer and forming a resist layer over the hard mask layer. The hard mask layer is configured to support selective deposition of a metal-containing layer on the resist layer, the selective deposition of the metal-containing layer on the resist layer occurring after pattern development. The method further includes exposing the multi-layer patterning material film stack to patterning radiation to form a desired pattern in the resist layer, developing the pattern formed in the resist layer, and selectively depositing the metal-containing layer on the developed pattern in the resist layer. The selective deposition avoids deposition of the metal-containing layer on portions of the hard mask layer corresponding to respective openings in the resist 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: The present disclosure relates to methods and apparatuses related to the deposition of a protective layer selective to an interlayer dielectric layer so that the protective layer is formed onto a top portion associated with the interlayer dielectric layer. In some embodiments, a method comprises: forming an interlayer dielectric layer on a substrate; covering a trench region with a metal liner, wherein the trench region is situated above the substrate and formed within the interlayer dielectric layer; and depositing a protective layer selective to the interlayer dielectric layer so that the protective layer is formed onto a top portion associated with the interlayer dielectric layer. In various embodiments, the depositing the protective layer comprises: repeatedly depositing the protective layer via a multi-deposition sequence; or depositing a self-assembled monolayer onto the top portion.

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 surface treatment composition and methods for improving adhesion of an organic layer on a titanium-containing hardmask includes forming a self-assembled monolayer on a surface of the titanium-containing hardmask prior to depositing the organic layer. The self-assembled monolayer is formed from a blend of alkyl phosphonic acids of formula (I): X(CH2)nPOOH2(I), wherein n is 6 to 16 and X is either CH3 or COOH, wherein a ratio of the methyl terminated (CH3) alkyl phosphonic acid to the carboxyl terminated (COOH) alkyl phosphonic acid ranges from 25:75 to 75:25.

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: Various methods and structures for fabricating a plurality of vertical fins in a vertical fin pattern on a semiconductor substrate where the vertical fins in the vertical fin pattern are separated by wide-open spaces, along a critical dimension, in a low duty cycle of 1:5 or lower. Adjacent vertical fins in the vertical fin pattern can be all separated by respective wide-open spaces, along a critical dimension, in a low duty cycle, and wherein pairs of adjacent vertical fins in the vertical fin pattern, along the critical dimension, are separated by a constant pitch value at near zero tolerance.

Abstract: A method of forming a semiconductor structure includes forming first and second stacked nanosheet channel structures on a semiconductor substrate, with each nanosheet channel structure including a plurality of stacked channel regions interspersed with sacrificial regions. In a resulting semiconductor structure, an N-type stacked nanosheet channel structure is formed on the semiconductor substrate, and a P-type stacked nanosheet channel structure is formed adjacent to the N-type stacked nanosheet channel structure on the semiconductor substrate. Each of the adjacent N-type and P-type stacked nanosheet channel structures includes a plurality of stacked channel regions with each such channel region being substantially surrounded by a gate dielectric layer and a gate work function metal layer.

Abstract: Forming a semiconductor structure, including epitaxially growing a first source drain region between a first fin in an N-FET region and a second fin in a P-FET region, forming a shallow trench isolation region separating the N-FET region and the P-FET region, conformally forming an insulator on exposed surfaces of the semiconductor structure, conformally forming a work function metal layer on exposed surfaces, conformally forming a liner, conformally forming an organic planarization layer, forming a titanium nitride layer, patterning a photo resist mask, forming an first opening between the N-FET region and the P-FET region, wherein a top surface of a portion of the liner is exposed at a bottom of the first opening, removing the portion of the liner between the N-FET region and the P-FET region and removing a portion of the work function metal layer between the N-FET region and the P-FET region.