The present invention aims to provide a dry etching agent having less load on global environment and capable of anisotropic etching without the use of special equipment and obtaining a good processing shape and to provide a dry etching method using the dry etching agent. The dry etching agent according the present invention contains at least a hydrofluoroalkylene oxide represented by the following chemical formula: CF.sub.3—C.sub.xH.sub.yF.sub.zO (where x=2 or 3; y=1, 2, 3, 4 or 5; and z=2x−1−y) and having an oxygen-containing three-membered ring. The dry etching method according to the present invention includes selectively etching of at least one kind of silicon-based material selected from the group consisting of silicon dioxide, silicon nitride, polycrystalline silicon, amorphous silicon and silicon carbide with the use of a plasma gas generated by plasmatization of the dry etching agent.

The present invention aims to provide a dry etching agent having less load on global environment and capable of anisotropic etching without the use of special equipment and obtaining a good processing shape and to provide a dry etching method using the dry etching agent. The dry etching agent according the present invention contains at least a hydrofluoroalkylene oxide represented by the following chemical formula: CF.sub.3—C.sub.xH.sub.yF.sub.zO (where x=2 or 3; y=1, 2, 3, 4 or 5; and z=2x−1−y) and having an oxygen-containing three-membered ring. The dry etching method according to the present invention includes selectively etching of at least one kind of silicon-based material selected from the group consisting of silicon dioxide, silicon nitride, polycrystalline silicon, amorphous silicon and silicon carbide with the use of a plasma gas generated by plasmatization of the dry etching agent.

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 semiconductor device includes a source/drain diffusion area, a first doped region and a gate. The source/drain diffusion area, defined between a first isolation structure and a second isolation structure, includes a source region, a drain region and a device channel. The first doped region, disposed along a first junction between the device channel and the first isolation structure, is separated from at least one of the source region and the drain region. The first doped region has a dopant concentration higher than that of the device channel. The gate is disposed over the source/drain diffusion area. The first doped region is located within a projected area of the gate onto the source/drain diffusion area, the first isolation structure and the second isolation structure. A length of the first doped region is shorter than a length of the gate in a direction from the source region to the drain region.

A semiconductor device is provided in the disclosure, including a substrate, multiple parallel fins protruding from the substrate and isolated by trenches, and a device insulating layer on the trenches between two fins, wherein the trench is provided with a central first trench and two second trenches at both sides of the first trench, and a depth of the first trench is deeper than a depth of the second trench, and the device insulating layer is provided with a top plane, a first trench and a second trench, and the fins protrude from the top plane, and the bottom surface of the second trench is lower than the bottom surface of the first trench.

Techniques are disclosed for non-planar transistors having varying channel widths (Wsi). In some instances, the resulting structure has a fin (or nanowires, nanoribbons, or nanosheets) comprising a first channel region and a second channel region, with a source or drain region between the first channel region and the second channel region. The widths of the respective channel regions are independent of each other, e.g., a first width of the first channel region is different from a second width of the second channel region. The variation in width of a given fin structure may vary in a symmetric fashion or an asymmetric fashion. In an embodiment, a spacer-based forming approach is utilized that allows for abrupt changes in width along a given fin. Sub-resolution fin dimensions are achievable as well.

Disclosed are DRAM devices and methods of forming DRAM devices. One method may include forming a plurality of trenches and angled structures, each angled structure including a first sidewall opposite a second sidewall, wherein the second sidewall extends over an adjacent trench. The method may include forming a spacer along a bottom surface of the trench, along the second sidewall, and along the first sidewall, wherein the spacer has an opening at a bottom portion of the first sidewall. The method may include forming a drain in each of the angled structures by performing an ion implant, which impacts the first sidewall through the opening at the bottom portion of the first sidewall. The method may include removing the spacer from the first sidewall, forming a bitline over the spacer along the bottom surface of each of the trenches, and forming a series of wordlines along the angled structures.

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 method may include providing a set of features in a mask layer, wherein a given feature comprises a first dimension along a first direction, second dimension along a second direction, orthogonal to the first direction, and directing an angled ion beam to a first side region of the set of features in a first exposure, wherein the first side region is etched a first amount along the first direction. The method may include directing an angled deposition beam to a second side region of the set of features in a second exposure, wherein a protective layer is formed on the second side region, the second side region being oriented perpendicularly with respect to the first side region. The method may include directing the angled ion beam to the first side region in a third exposure, wherein the first side region is etched a second amount along the first direction.

A method includes forming a first electrically conductive layer on a first side of a dielectric insulation layer, forming a structured mask layer on a side of the first electrically conductive layer that faces away from the dielectric insulation layer, forming at least one trench in the first electrically conductive layer, said at least one trench extending through the entire first electrically conductive layer to the dielectric insulation layer, forming a coating which covers at least the bottom and the side walls of the at least one trench, and removing the mask layer after the coating has been formed.