A method of depositing a material on one of two, but not both, sidewalls of a raised structure formed on a substrate includes tilting a normal of the substrate away from a source of the deposition material or tilting the source of the deposition material away from the normal of the substrate. The method may be implemented by a plasma-enhanced chemical vapor deposition (PECVD) technique.

A method of manufacturing a semiconductor device, including: providing a substrate including a first cell and a second cell, the first cell and the second cell are arranged in a first direction; forming a plurality of first metal strips arranged in a second direction and extending in the first direction on a first plane; forming a first trench over a boundary between the first cell and the second cell, a bottom surface of the first trench is located on a second plane over the first plane; filling the first trench with a non-conductive material, resulting in a separating wall extending in the first direction; and fort plurality of second metal strips extending in the second direction on a third plane over the second plane and including a first second metal strip and a second second metal strip separated by the separating wall.

In one exemplary aspect, the present disclosure is directed to a method for lithography patterning. The method includes providing a substrate and forming a target layer over the substrate. A patterning layer is formed by depositing a first layer having an organic composition; depositing a second layer including over 50 atomic percent of silicon; and depositing a photosensitive layer on the second layer. In some implementations, the second layer is deposited by ALD, CVD, or PVD processes.

A pick-up structure for a memory device and method for manufacturing memory device are provided. The pick-up structure includes a substrate and a plurality of pick-up electrode strips. The substrate has a memory cell region and a peripheral pick-up region adjacent thereto. The pick-up electrode strips are parallel to a first direction and arranged on the substrate in a second direction. The second direction is different from the first direction. Each pick-up electrode strip includes a main part in the peripheral pick-up region and an extension part extending from the main part to the memory cell region. The main part is defined by fork-shaped patterns of a first mask layer. The extension part has a width less than that of the main part, and the extension part has a side wall surface aligned with a side wall surface of the main part.

Techniques described herein relate to methods, apparatus, and systems for promoting adhesion between a substrate and a metal-containing photoresist. For instance, the method may include receiving the substrate in a reaction chamber, the substrate having a first material exposed on its surface, the first material including a silicon-based material and/or a carbon-based material; generating a plasma from a plasma generation gas source that is substantially free of silicon, where the plasma includes chemical functional groups; exposing the substrate to the plasma to modify the surface of the substrate by forming bonds between the first material and chemical functional groups from the plasma; and depositing the metal-containing photoresist on the modified surface of the substrate, where the bonds between the first material and the chemical functional groups promote adhesion between the substrate and the metal-containing photoresist.

A semiconductor structure is provided. The semiconductor structure includes a substrate, a target layer on the substrate, and a hard mask layer doped with a group IV-A element on the target layer. The number of sp3 orbital bonds in the hard mask layer is greater than the number of sp2 orbital bonds.

A method of manufacturing a semiconductor device includes forming a gate oxide layer on a substrate, where the substrate includes a high voltage region and a low voltage region. The gate oxide layer is disposed in the high voltage region. Wet etching is performed on the gate oxide layer to reduce a thickness of the gate oxide layer. Multiple trenches are formed around the high voltage region in the substrate, where forming the trenches includes removing an edge of the gate oxide layer to make the thickness of the gate oxide layer uniform. An insulating material is filled in the trenches to form multiple shallow trench isolation structures, where an upper surface of the shallow trench isolation structures close to the edge of the gate oxide layer is coplanar with an upper surface of the gate oxide layer.

A semiconductor structure includes: a plurality of calibration reference features disposed on a substrate and spaced apart from each other in a first direction; and a plurality of columns of first active features and a plurality of columns of second active features respectively disposed on opposite sides of the calibration reference features, wherein each of the columns of first active features is spaced apart from each other in a second direction, each of the columns of second active features is spaced apart from each other in the second direction, and the calibration reference features, the first active features, and the second active features are disposed on the same layer and are a portion of the substrate.

A substrate with a conductive film for manufacturing a reflective mask which has a rear-surface conductive film with high mechanical strength and is capable of correcting positional deviation of the reflective mask from the rear surface side by a laser beam or the like. A substrate with a conductive film has a conductive film formed on one surface of a main surface of a mask blank substrate used for lithography, wherein the conductive film includes a transparent conductive layer provided on a substrate side and an upper layer provided on the transparent conductive layer, the conductive film has a transmittance of 10% or more for light of wavelength 532 nm, the upper layer is made of a material including tantalum (Ta) and boron (B), and the upper layer has a film thickness of 0.5 nm or more and less than 10 nm.

A method of defining a pattern includes forming a plurality of cut shapes and a first plurality of openings within a first layer of a multi-layer hard mask to expose first portions of the second layer. A plurality of etch stops is formed by implanting an etch rate modifying species in a portion of the plurality of cut shapes. The first layer is directionally etched at the plurality of cut shapes such that the plurality of etch stops remain. A spacer layer is formed on the first layer and the first portions. A second plurality of openings is formed within the spacer layer to expose second portions of the second layer. The spacer layer is directionally etched to remove the spacer layer from sidewalls of the plurality of etch stops. Portions of the second layer exposed through the first plurality of openings and the second plurality of openings are etched.