A band-shaped Si pillar having a mask material layer on the top portion thereof is formed on a P+ layer. SiGe layers having mask material layers on the top portions thereof are then formed in contact with the side surfaces of the band-shaped Si pillar and the surfaces of N+ layers and the P+ layer. Si layers having mask material layers on the top portions thereof are then formed in contact with the side surfaces of the SiGe layers and the surfaces of the N+ layers. The outer peripheries of the bottom portions of the Si layers are then removed using the mask material layers as a mask to form band-shaped Si pillars. The mask material layers and the SiGe layers are then removed. Si pillars separated in the Y direction are then formed in the band-shaped Si pillars.

Embodiments relate to a semiconductor structure and a method for fabricating the same. The method includes: providing a substrate, a first trench being formed in the substrate; forming a protective layer in the first trench, the protective layer covering a side wall and a bottom of the first trench; etching the protective layer and the substrate at the bottom of the first trench to form second trenches; forming a passivation layer at a bottom of each of the second trenches; and etching a side wall of each of the second trenches to form a groove, and forming a dielectric layer in the groove. The method can eliminate a process of forming a bit line contact structure, thereby reducing resistance of a bit line and simplifying fabrication processes of the bit line.

A method for forming a semiconductor structure includes the following: providing a semiconductor substrate, in which stack structures and isolation structures alternately arranged along a first direction are formed on the semiconductor substrate; forming a support structure in the stack structures and the isolation structures; etching the stack structures and the isolation structures to form multiple zigzag first semiconductor pillars in an array arrangement along the first direction and a second direction, in which an interspace is formed between the zigzag first semiconductor pillars; each zigzag first semiconductor pillar comprises first convex structures and first concave structures alternately arranged along a third direction, and is supported by the support structure; the first direction, the second direction and the third direction are perpendicular to one another, and the second direction is perpendicular to a top surface of the semiconductor substrate; forming capacitor structures the interspace.

A wafer having a semiconductor substrate including a peripheral region and a central region, an insulating layer and a semiconductor layer is prepared first. Next, a plurality of trenches penetrating through the semiconductor layer and the insulating layer and reaching an inside of the semiconductor substrate are formed. Next, an inside of each of the plurality of trenches is filled with an insulating film, so that a plurality of element isolating portions is formed. Next, in the central region, the semiconductor layer exposed from a resist pattern is removed. The end portion closest to the outer edge of the semiconductor substrate among ends of the resist pattern used for removing the semiconductor layer in the central region is formed so as to be positioned closer to the outer edge of the semiconductor substrate than a position of the end portion closest to the outer edge of the semiconductor substrate among ends of the resist pattern used for forming the trenches.

The present description concerns a method of forming a cavity in a substrate comprising: the forming of an etch mask comprising, opposite the location of the cavity, a plurality of sets of openings, the ratio between the openings and the mask of each set being selected according to the desired profile of the cavity opposite the surface of the mask having the set inscribed therein; and the wet etching of the substrate through the openings.

A method for manufacturing a semiconductor device includes forming a plurality of first semiconductor layers alternately stacked with a plurality of second semiconductor layers on a semiconductor substrate, and laterally recessing the plurality of first semiconductor layers with respect to the plurality of second semiconductor layers to form a plurality of vacant areas on lateral sides of the plurality of first semiconductor layers. In the method, a plurality of first inner spacers are formed on the lateral sides of the plurality of first semiconductor layers in respective ones of the plurality of vacant areas, and a plurality of second inner spacers are formed on sides of the plurality of first inner spacers in the respective ones of the plurality of vacant areas. The method also includes laterally recessing the plurality of second semiconductor layers, and growing a plurality of source/drain regions from the plurality of second semiconductor layers.

Double patterning techniques described herein may reduce corner rounding, etch loading, and/or other defects that might otherwise arise during formation of a deep trench isolation (DTI) structure in a pixel array. The double patterning techniques include forming a first set of trenches in a first direction and forming a second set of trenches in a second direction in a plurality of patterning operations such that minimal to no etch loading and/or corner rounding is present at and/or near the intersections of the first set of trenches and the second set of trenches.

A plasma processing apparatus includes a chamber having a gas inlet and a gas outlet; a plasma generator; and a controller configured to cause: (a) providing a substrate including a silicon-containing film and a mask formed on the film; (b) etching the silicon-containing film through the mask to the first depth, thereby forming a recess in the silicon-containing film; (c) forming a protection film at least on the mask and a side wall of the recess formed on the silicon-containing film after (a); and (d) etching the silicon containing film through the mask to a second depth, the second depth being greater than the first depth.

A first mask material layer on a Si pillar 7a and a first material layer around a side surface of a top portion of the Si pillar 7a are formed. A second material layer is then formed on an outer periphery of the first material layer. The first mask material layer and the first material layer are then etched by using the second material layer as a mask. A thin SiGe layer, a p.sup.+ layer 23a, and a SiO.sub.2 layer 24a are then formed in a recessed portion formed around the Si pillar 7a. The exposed side surface of the thin SiGe layer is oxidized to form a SiO.sub.2 layer 26a. A TiN layer and a W layer, which are gate conductor layers, are etched by using the SiO.sub.2 layers 24a and 26a as masks to form a TiN layer 29a and a W layer 30a. In plan view, the Si pillar 7a, the p.sup.+ layer 23a with a small diode junction resistance, and the TiN layer 29a and the W layer 30a, which are gate line conductor layers, thus have a self-alignment relationship, and the p.sup.+ layer 23a and the TiN layer 29a are self-aligned with each other with the HfO.sub.2 layer 28 and the SiO.sub.2 layer 26a therebetween in the vertical direction.

A method for manufacturing a relaxed epitaxial InGaN layer from a GaN/InGaN substrate comprising the following steps: a) providing a first stack comprising a GaN or InGaN layer to be porosified and a barrier layer, b) transferring the GaN or InGaN layer to be porosified and the barrier layer to a porosification support, in such a way as to form a second stack, c) forming a mask on the GaN or InGaN layer to be porosified, d) porosifying the GaN or InGaN layer through the mask, e) transferring the GaN or InGaN porosified layer and the barrier layer to a support of interest, f) forming an InGaN layer by epitaxy on the barrier layer, whereby a relaxed epitaxial InGaN layer is obtained.