Abstract: An EUV lithographic structure and methods according to embodiments of the invention includes an EUV photosensitive resist layer disposed directly on an oxide hardmask layer, wherein the oxide hardmask layer is doped with dopant ions to form a doped oxide hardmask layer so as to improve adhesion between the EUV lithographic structure and the oxide hardmask. The EUV lithographic structure is free of a separate adhesion layer.

Abstract: A method includes applying a first metallic layer having a first metallic material onto a substrate of a semiconductor component. The method further includes removing portions of the first metallic layer to form a first metallic line. The method further includes creating an opening in the first metallic line. The method also includes depositing a dielectric material on the substrate. The method further includes forming at least one trench in the dielectric material. The method also includes depositing a second metallic material within the at least one trench to form a second metallic line. At least the first and second metallic lines and the dielectric material form an interconnect structure of the semiconductor component.

Abstract: A method of forming a semiconductor structure includes, in a radio frequency (RF) deposition chamber, depositing a titanium film using physical vapor deposition and forming a graded hard mask film by reactive sputtering the titanium film with nitrogen in the RF deposition chamber. The graded hard mask film is a titanium nitride film with a graded vertical concentration of nitrogen. The method may further include, during deposition of the titanium film and during formation of the graded hard mask film, modulating one or more parameters of the RF deposition chamber, such as modulating an auto capacitance tuner (ACT) current, modulating the RF power, and modulating the pressure of the RF deposition chamber.

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 integrating a multiple patterning scheme includes forming a memorization layer over a plurality of mandrels and a plurality of non-mandrels, and applying an exposure scheme to the memorization layer to form at least one mandrel cut pattern and at least one non-mandrel cut pattern.

Abstract: Selective gas etching for self-aligned pattern transfer uses a first block and a separate second block formed in a sacrificial layer to transfer critical dimensions to a desired final layer using a selective gas etching process. The first block is a first hardmask material that can be plasma etched using a first gas, and the second block is a second hardmask material that can be plasma etched using a second gas separate from the first gas. The first hardmask material is not plasma etched using the second gas, and the second hardmask material is not plasma etched using the first gas.

Abstract: Embodiments of the present disclosure include measurement systems and grating pattern arrays. The measurement systems include multiple subsystems for creating diffraction patterns or magnified real images of grating regions on a substrate. The measurements systems are configured to reflect and transmit light, and the reflected and transmitted beams create diffraction patterns and enlarged images. The diffraction patterns and images provide information on grating pitch and angles of grating regions. Grating pattern arrays disposed on a substrate include main regions and reference regions. The reference regions are used to locate corresponding main regions. The measurement systems do not include a rotating stage, and thus precise control of rotation of a stage is not needed.

Abstract: Methods and systems for performing an electronic design. A layout of a via of an electronic design is obtained and a determination is made if the layout of the via satisfies one or more retargeting conditions, at least one of the retargeting conditions being that a first edge of a metal line is within a specified distance from a first edge of the via and a second edge of the metal line is within the specified distance from a second edge of the via, the first edge of the metal line being parallel to the first edge of the via and the second edge of the metal line being parallel to the second edge of the via; and reducing a resistance of the via by the layout of the via is retargeted in response to the retargeting conditions being satisfied.

Abstract: Embodiments of the invention include methods and structures for controlling developer critical dimension (DCD) variations across a wafer surface. Aspects of the invention include an apparatus having developer tubing and an internal cam. The internal cam is coupled to a fixed axis. A flexible divider is positioned between the developer tubing and the internal cam. The flexible divider is coupled to the internal cam such that rotation of the internal cam about the fixed axis is operable to change an inner diameter of the developer tubing.

Abstract: An Nblock layer is deposited onto a semiconductor substrate that includes metal deposits. A titanium nitride (TiN) layer is deposited directly onto the Nblock layer; an oxide layer is deposited directly onto the TiN layer; and a via hole is formed through the oxide and TiN layer to contact bottom interconnect. The via hole is aligned to one of the metal deposits in the substrate.

Abstract: A device and a method for forming the device is contemplated. The device and method include patterning a hardmask formed over a substrate. The hardmask is modified by raising an annealing temperature of the hardmask from a first annealing temperature to a second annealing temperature using ion implantation. The hardmask is annealed with a laser beam using a process temperature between the first annealing temperature and the second annealing temperature.

Abstract: A semiconductor device includes a stack structure having at least first, second and third interconnect levels. Each interconnect level has a patterned metal conductor including a first metallic material. A via spans the second and third interconnect levels and electrically couples with the patterned metal conductor of the first interconnect level. At least a segment of the super via includes a second metallic material different from the first metallic material.

Abstract: An imaging system and a method of creating composite images are provided. The imaging system includes one or more lens assemblies coupled to a sensor. When reflected light from an object enters the imaging system, incident light on the metalens filter systems creates filtered light, which is turned into composite images by the corresponding sensors. Each metalens filter system focuses the light into a specific wavelength, creating the metalens images. The metalens images are sent to the processor, wherein the processor combines the metalens images into one or more composite images. The metalens images are combined into a composite image, and the composite image has reduced chromatic aberrations.

Abstract: A method is presented for forming interlayer connections in a semiconductor device. The method includes patterning an etch stack to provide for a plurality of interlayer connections, etching guide layers following the etch stack to a first capping layer to form a plurality of guide openings, concurrently exposing a first plurality of conductive lines and a second plurality of conductive lines to form a plurality of interlayer connection openings by etching through the plurality of guide openings to remove the first capping layer, an interlayer dielectric, and a second capping layer, and depositing a metal fill in the plurality of interlayer connection openings to form the plurality of interlayer connections.

Abstract: A photoresist is developed on a semiconductor wafer. The wafer is introduced into a controlled cold temperature environment and is maintained there until inelastic thermal contraction of the developed photoresist material results in reducing the critical dimension (CD) of the photoresist by not less than 10% from its value before exposure to the controlled cold temperature environment. Then the semiconductor wafer is removed from the controlled cold temperature environment.

Abstract: Techniques for single trench damascene interconnect formation using TiN HMO are provided. In one aspect, a method for forming interconnects on a substrate includes: forming an underlayer on the substrate; forming a hardmask on the underlayer; patterning trenches in the hardmask that extend down to the underlayer; forming the interconnects in the trenches; removing the hardmask; and burying the interconnects in an ILD. The trenches can be patterned in the hardmask using a process such as sidewall image transfer. An interconnect structure is also provided.

Abstract: Various semiconductor fabrication methods and structures are disclosed for cost effectively fabricating a self-aligned contact. A source-drain active region is on a substrate and horizontally extends to sidewall spacers of two adjacent gate stacks on the substrate. A conductive material layer including Titanium is formed by selective deposition on the source-drain active area. An interlevel dielectric (ILD) layer is deposited over the source-drain active area and the two gate stacks. Vertical directional etching in the ILD layer forms a vertical trench contacting the conductive material layer. Selective wet etching in the vertical trench selectively etches the conductive material layer and forms a void therein. Deposition of a second conductive material in the vertical trench fills the vertical trench, including the void, and the second conductive material contacts the top surface of the source-drain active area to form a source-drain self-aligned contact.

Abstract: Embodiments of the present disclosure generally relate to processing a workpiece containing a substrate during deposition, etching, and/or curing processes with a mask to have localized deposition on the workpiece. A mask is placed on a first layer of a workpiece, which protects a plurality of trenches from deposition of a second layer. In some embodiments, the mask is placed before deposition of the second layer. In other embodiments, the second layer is cured before the mask is deposited. In other embodiments, the second layer is etched after the mask is deposited. Methods disclosed herein allow the deposition of a second layer in some of the trenches present in the workpiece, while at least partially preventing deposition of the second layer in other trenches present in the workpiece.

Abstract: Methods and systems for performing an electronic design. A layout of a via of an electronic design is obtained and a determination is made if the layout of the via satisfies one or more retargeting conditions, at least one of the retargeting conditions being that a first edge of a metal line is within a specified distance from a first edge of the via and a second edge of the metal line is within the specified distance from a second edge of the via, the first edge of the metal line being parallel to the first edge of the via and the second edge of the metal line being parallel to the second edge of the via; and reducing a resistance of the via by the layout of the via is retargeted in response to the retargeting conditions being satisfied.

Abstract: A technique relates to a semiconductor device. Mandrels are formed on a substrate, the mandrels including a first metal layer. A second metal layer is formed on the substrate adjacent to the first metal layer, the first and second metal layers being separated by spacer material.