A non-conformal, highly selective liner for etch methods in semiconductor devices is described. A method comprises forming a film stack on a substrate; etching the film stack to form an opening; depositing a non-conformal liner in the opening; etching the non-conformal liner from the bottom of the opening; and selectively etching the film stack relative to the non-conformal liner to form a logic or memory hole. The non-conformal liner comprises one or more of boron, carbon, or nitrogen.

Embodiments relate to the field of semiconductors, and provide a semiconductor structure, including a substrate and connection lines. Structural cells arranged in an array are provided on the substrate, and include transistor groups arranged in a first direction, and the transistor groups include multi-layer transistors extending in a second direction. The first direction is perpendicular to the second direction, and both are parallel to a surface of the substrate. The structural cells further include bit lines extending in a third direction, the bit lines are electrically connected to the multi-layer transistors in the same transistor group, where the third direction is perpendicular to the surface of the substrate. The connection lines are connected to the bit lines in the structural cells in one-to-one correspondence, and one bit line in the structural cells arranged in the array is connected to the same connection line.

A semiconductor structure, a method for manufacturing the same and a memory are provided. The semiconductor structure includes a substrate, multiple first active pillars above the substrate, a memory structure, multiple transistors, and multiple second active pillars. The multiple first active pillars are arranged in an array along a first direction and a second direction. The substrate includes an isolation structure on which the first active pillars are located. The memory structure includes first electrode layers, a dielectric layer and a second electrode layer. The first electrode layer covers a sidewall of the first active pillar, the dielectric layer covers at least surfaces of the first electrode layers, the second electrode layer covers a surface of the dielectric layer. Each of the second active pillars is located above a corresponding one of the first active pillars; a channel structure of each transistor is located in the second active pillar.

The method for forming the capacitor stack structure includes: providing a substrate on which a plurality of first laminated structures arranged in a first direction and a first isolation structure located between every two adjacent the first laminated structures are formed, and the first laminated structure including first semiconductor layers and second semiconductor layers stacked alternately; forming, in the first laminated structures and the first isolation structures, first trench extending in the first direction, the spacing in a second direction between the adjacent remaining first semiconductor layers is greater than the spacing between the adjacent remaining second semiconductor layers; forming a support structure in the first trench, and removing the first semiconductor layers from the first laminated structure to form a first space; and forming capacitor structures in the first space to form a capacitor stack structure.

A method for manufacturing a semiconductor structure includes the following operations. A base and a dielectric layer arranged on the base are provided. A first conductive pillar, a second conductive pillar and a third conductive pillar arranged in the dielectric layer are formed. A mask layer is formed. A portion of a thickness of the third conductive pillar is etched by using the third mask layer as a mask to form a third lower conductive pillar and a third upper conductive pillar stacked on one another, in which the third upper conductive pillar, the third lower conductive pillar and the dielectric layer are configured to form at least one groove. A cover layer filling the at least one groove is formed, in which the cover layer exposes the top surface of the third upper conductive pillar.

A semiconductor die includes semiconductor substrate and interconnection structure. Interconnection structure includes first conductive lines, first conductive patterns, first pillar stacks, second pillar stacks, gate patterns. First conductive lines extend parallel to each other in first direction and are embedded in interlayer dielectric layer. First conductive patterns are disposed in row along first direction and are embedded in interlayer dielectric layer beside first conductive lines. First pillar stacks include first pairs of metallic blocks separated by first dielectric material blocks. Second pillar stacks include second pairs of metallic blocks separated by second dielectric material blocks. Each second pillar stack is electrically connected to respective first conductive pattern. Gate patterns extend substantially perpendicular to first conductive lines. Each gate pattern directly contacts one respective second pillar stack and extends over a group of first pillar stacks.

Semiconductor devices and corresponding methods of manufacturing the same are disclosed. For example, a semiconductor device includes a first transistor comprising a first channel region. The first channel region includes one or more first nanostructures formed of a semiconductor material. The semiconductor device includes a second transistor disposed vertically with respect to the first transistor and comprising a second channel region. The second channel region includes one or more second nanostructures formed of a conductive oxide material.

A semiconductor structure includes a substrate and a plurality of word lines located on a top surface of the substrate. Each of the word lines extends in a direction perpendicular to the top surface of the substrate. The plurality of word lines are arranged at intervals along a first direction. Any two adjacent ones of the word lines are arranged in an at least partially staggered manner along the first direction. The first direction is a direction parallel to the top surface of the substrate.

Provided are a semiconductor structure and a method for manufacturing the same. The semiconductor structure includes: a base; a bit line; and a semiconductor channel including a first doped region, a channel region, and a second doped region that are sequentially arranged, where the first doped region contacts the bit line, and the first doped region, the channel region, and the second doped region are doped with first-type doped ions. The channel region is further doped with second-type doped ions, enabling a concentration of majority carriers in the channel region to be less than a concentration of majority carriers in the first doped region and a concentration of majority carriers in the second doped region. The first-type doped ions are one of N-type ions or P-type ions, and the second-type doped ions are the other of N-type ions or P-type ions.

A method for forming a semiconductor structure comprises: providing a substrate, which includes a first area and a second area arranged in sequence in a second direction, the first area including active layers arranged at intervals in a third direction; forming an initial gate structure located on a surface of each active layer in the first area; etching the initial gate structures to form comb-shaped gate structures stacked in a third direction, each comb-shaped gate structure including first gate structures arranged at intervals in the first direction; and forming bit line structures extending in the third direction and capacitor structures extending in the second direction in the second area, the bit line structures and the capacitor structures are connecting to the first gate structures.