Abstract: A semiconductor structure and a method for fabricating the same. The semiconductor structure includes at least a first channel region and a second channel region. The first channel region and the second channel region each include metal gate structures surrounding a different nanosheet channel layer. The metal gate structures of the first and second channel regions are respectively separated from each other by an unfilled gap. The method includes forming a gap fill layer between and in contact with gate structures surrounding nanosheet channel layers in multiple channel regions. Then, after the gap fill layer has been formed for each nanosheet stack, a masking layer is formed over the gate structures and the gap fill layer in at least a first channel region. The gate structures and the gap fill layer in at least a second channel region remain exposed.

Abstract: An adhesion promoter composition comprising at least one of the following compounds: (a) a cyclic compound having the formula: (b) a non-cyclic compound having the formula: wherein R1 and R2 each independently represents a non-photoactive phenyl, a photoactive phenyl or a C1-C4 alkyl; R3 represents a non-photoactive phenyl; R4 represents a photoactive phenyl; W represents Si or Ge; n represents an integer of value greater than 1; m represents an integer between 0 and 1.

Abstract: A method includes forming a first insulating layer having one or more vias formed in at least a portion of the first insulating layer. The vias are filled with a first metallic material. A cap layer is deposited on a top surface of the first insulating layer and a top surface of the one or more vias and a second insulating layer is deposited on a top surface of the cap layer. One or more openings are formed in the second insulating layer and the cap layer. A self-assembled monolayer is formed on an exposed top surface of the first metallic material in the one or more vias. A barrier layer is formed on at least the exposed surface of the one or more openings. The self-assembled monolayer is removed and the one or more openings are filled with a second metallic material.

Abstract: One or more embodiments described herein include systems, and/or methods that facilitate fabrication of a semiconductor device using a spacer lithography-etch process. According to an embodiment, a method can comprise performing a first lithography exposure and etch over a first layer of a semiconductor device, where the first lithography exposure and etch comprises forming one or more mandrels on a first region of a second layer by employing a first photoresist layer. The method can further comprise forming one or more spacers on a sidewall of the one or more mandrels and covering a second region of the second layer, where the second region is adjacent to the one or more mandrels. The method can further comprise forming a cut over a third region of the second layer and filling the third region with first material.

Abstract: Techniques regarding the replenishment of one or more hard mask layers to facilitate one or more etching processes are provided. For example, one or more embodiments described herein can comprise a method, which can comprise replenishing an oxide layer onto a surface of a semiconductor substrate by thermally oxidizing the surface of the semiconductor substrate. The oxide layer can facilitate selective etching of the semiconductor substrate.

Abstract: A photolithography patterning stack and method for repairing defects in the stack. The stack includes an organic planarization layer, a hardmask layer, and a plurality of patterned photoresist lines in contact with the hardmask layer. A plurality of trenches is situated between the plurality of patterned photoresist lines. Each trench exposes a portion of the hardmask layer. A repairing layer is formed in contact with and only bonded to surfaces of the plurality of patterned photoresist lines. The method includes forming a photolithographic patterning stack. The stack includes at least a hardmask layer formed on one or more underlayers and a photoresist layer formed in contact with the hardmask layer. The photoresist layer is patterned into a plurality of patterned portions. A repairing layer is formed in contact with and only bonded to surfaces of each patterned portion of the plurality of portions.

Abstract: A semiconductor structure comprises a semiconductor substrate, an N-type stacked nanosheet channel structure formed on the semiconductor substrate, and a P-type stacked nanosheet channel structure 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 comprises 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, and with the gate work function metal layer being separated from the channel regions by the gate dielectric layer. The gate dielectric and gate work function metal layers of the adjacent N-type and P-type stacked nanosheet channel structures are substantially eliminated from a shared gate region between the adjacent N-type and P-type stacked nanosheet channel structures.

Abstract: Semiconductor devices include a semiconductor fin. A gate stack is formed over the semiconductor fin. Source and drain regions are formed at respective sides of the gate stack. A dielectric line is formed parallel to the gate stack. An interlayer dielectric is formed between the gate stack and the dielectric line. A top surface of the interlayer dielectric between the gate stack and the dielectric line is not recessed.

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 of manufacturing a semiconductor device includes forming a hard mask layer over a substrate and activating a surface of the hard mask layer to form a surface active layer over the hard mask layer. A resist layer is formed over the hard mask layer and a metal-containing layer is selectively formed over the surface active layer in at least one trench defined between portions of the resist layer. The resist layer is removed to define a pattern between portions of the selectively formed metal-containing layer and the hard mask layer is etched in accordance with the pattern. The etched pattern is transferred to at least a portion of the substrate and at least a portion of the hard mask layer, surface active layer, and metal-containing layer are removed.

Abstract: Semiconductor structures fabricated via extreme ultraviolet (EUV) lithographic patterning techniques implementing directional deposition on a EUV resist mask improves selectivity and critical dimension control during the patterning of features in multiple layers of the semiconductor substrate. A semiconductor structure includes a substrate structure having an extreme ultraviolet resist mask disposed over one or more additional layers of the substrate structure. The extreme ultraviolet resist mask defines patterning features. A hard mask layer including a hard mask material is disposed on the extreme ultraviolet resist mask and covers the patterning features of the extreme ultraviolet resist mask.

Abstract: A method for fabricating a semiconductor device with multiple threshold voltages includes masking a substrate structure to selectively form work-function metal layers on vertical field effect transistors. In the method, a first work function metal layer is formed on a high-k dielectric layer of a substrate structure comprising vertical field effect transistors. The first work function metal layer and the high-k dielectric layer are etched to form gate regions for each vertical field effect transistor. A resist mask is formed over a first of the vertical field effect transistors. The resist mask isolates the first of the vertical field effect transistors from a second of the vertical field effect transistors. A second work function metal layer is selectively formed on the first work function metal layer of the gate region of the second of the vertical field effect transistors. The resist mask is then removed.

Abstract: Extreme ultraviolet (EUV) lithographic patterning methods are provided which implement directional deposition on the EUV resist mask to improve selectivity and critical dimension control during the patterning of features in multiple layers. A hard mask material is deposited on a substrate structure using directional deposition. The hard mask material forms a hard mask layer that covers patterning features of an EUV resist mask of the substrate structure. The hard mask material is etched selective to a layer underlying the EUV resist mask to remove portions of the hard mask material that were deposited on the underlying layer during the directional deposition without uncovering the patterning features of the EUV resist mask. At least one layer of the substrate structure is patterned based on the EUV resist mask and the hard mask layer.

Abstract: A method for fabricating a semiconductor device with multiple threshold voltages includes masking a substrate structure to selectively form work-function metal layers on vertical field effect transistors. In the method, a first work function metal layer is formed on a high-k dielectric layer of a substrate structure comprising vertical field effect transistors. The first work function metal layer and the high-k dielectric layer are etched to form gate regions for each vertical field effect transistor. A resist mask is formed over a first of the vertical field effect transistors. The resist mask isolates the first of the vertical field effect transistors from a second of the vertical field effect transistors. A second work function metal layer is selectively formed on the first work function metal layer of the gate region of the second of the vertical field effect transistors. The resist mask is then removed.

Abstract: The invention herein includes enhancing the surface of an amorphous silicon hardmask through implantation of nonpolar, hydrophobic elements, resulting in increased hydrophobicity and increased resist adhesion of the amorphous silicon surface. According to the invention, implanting the hydrophobic elements may involve introduction of the hydrophobic elements into the surface of the amorphous silicon by way of low energy implantation and plasma treatment. The implanted hydrophobic element may be Boron, Xenon, Fluorine, Phosphorus, a combination thereof, or other hydrophobic elements. According to the invention, the surface of the amorphous silicon is enhanced with 10-15% hydrophobic element, however in other embodiments, this composition may be adjusted as needed. In any case, however, the invention herein includes maintaining an etch selectivity of the bulk amorphous silicon hardmask.

Abstract: A method of manufacturing a semiconductor device includes forming a hard mask layer over a substrate and activating a surface of the hard mask layer to form a surface active layer over the hard mask layer. A resist layer is formed over the hard mask layer and a metal-containing layer is selectively formed over the surface active layer in at least one trench defined between portions of the resist layer. The resist layer is removed to define a pattern between portions of the selectively formed metal-containing layer and the hard mask layer is etched in accordance with the pattern. The etched pattern is transferred to at least a portion of the substrate and at least a portion of the hard mask layer, surface active layer, and metal-containing layer are removed.

Abstract: A self-priming resist may be formed from a first random copolymer forming a resist and a polymer brush having the general formula poly(A-r-B)-C-D, wherein A is a first polymer unit, B is a second polymer unit, wherein A and B are the same or different polymer units, C is a cleavable unit, D is a grafting group and r indicates that poly(A-r-B) is a second random copolymer formed from the first and second polymer units. The first random copolymer may be the same or different from the second random polymer. The self-priming resist can create a one-step method for forming an adhesion layer and resist by using the resist/brush blend.

Abstract: A semiconductor structure comprises a semiconductor substrate, and a multi-layer patterning material film stack formed on the semiconductor substrate. The patterning material film stack comprises at least a hard mask layer and a resist layer formed over the hard mask layer. The hard mask layer is configured to support selective deposition of a metal-containing layer on a developed pattern of the resist layer through inclusion in the hard mask layer of one or more materials inhibiting deposition of the metal-containing layer on portions of the hard mask layer corresponding to respective openings in the resist layer. The hard mask layer illustratively comprises, for example, at least one of a grafted self-assembled monolayer configured to inhibit deposition of the metal-containing layer, and a grafted polymer brush material configured to inhibit deposition of the metal-containing layer.

Abstract: A method of optimizing a lithographic process for semiconductor fabrication includes determining that a semiconductor wafer experienced a photoresist exposure delay. At least one operating parameter of a post exposure baking process is adjusted based on the semiconductor wafer having experienced the photoresist exposure delay. The post exposure baking process is performed on the semiconductor wafer utilizing the adjusted at least one operating parameter.

Abstract: Semiconductor devices and methods are provided to fabricate fin field-effect transistor (FinFET) devices having uniform fin height profiles. For example, uniformity of fin height profiles for FinFET devices is obtained by implementing a gate oxide removal process which is designed to prevent etching of an isolation layer (e.g., a shallow trench isolation layer) formed of an oxide material during removal of, e.g., sacrificial gate oxide layers of dummy gate structures during a replacement metal gate process.