The present disclosure generally relates to fine geometry electrical circuits and methods of manufacture thereof. More specifically, methods for forming 3D cross-point memory arrays using a single nano-imprint lithography step and no photolithography are disclosed. The method includes imprinting a multilevel topography pattern, transferring the multilevel topography pattern to a substrate, filling the etched multilevel topography pattern with hard mask material, planarizing the hard mask material to expose a first portion of the substrate, etching a first trench in the first portion of the substrate, depositing a first plurality of layers in the first trench, planarizing the hard mask material to expose a second portion of the substrate, etching a second trench in the second portion of the substrate and depositing a second plurality of layers in the second trench. The method is repeated until a 4F.sup.2 3D cross-point memory array has been formed.

A vertical-type nonvolatile memory device has a multi-stack structure with reduced susceptibility to mis-alignment of a vertical channel layer. This nonvolatile memory device includes: (i) a main chip area including a cell area and an extension area arranged to have a stepped structure, with the cell area and the extension area formed in a multi-stack structure, and (ii) an outer chip area, which surrounds the main chip area and includes a step key therein. The main chip area includes a first layer on a substrate and a second layer on the first layer. A lower vertical channel layer is arranged in the first layer. The step key includes an alignment vertical channel layer, and a top surface of the alignment vertical channel layer is lower than a top surface of the lower vertical channel layer.

A method used in forming an array of memory cells comprises forming a vertical stack comprising transistor material directly above insulator material. A mask is used to subtractively etch both the transistor material and thereafter the insulator material to form a plurality of pillars that individually comprise the transistor material and the insulator material. The insulator material is laterally-recessed from opposing lateral sides of individual of the pillars selectively relative to the transistor material of the individual pillars. The individual pillars are formed to comprise a first capacitor electrode that is in void space formed from the laterally recessing. Capacitors are formed that individually comprise the first capacitor electrode of the individual pillars. A capacitor insulator is aside the first capacitor electrode of the individual pillars and a second capacitor electrode is laterally-outward of the capacitor insulator. Vertical transistors are formed above the capacitors and individually comprise the transistor material of the individual pillars. Other aspects, including structure independent of method, are disclosed.

A method used in forming an array of memory cells comprises forming a vertical stack comprising transistor material directly above and directly against a first capacitor electrode material. A mask is used to subtractively etch both the transistor material and thereafter the first capacitor electrode material to form a plurality of pillars that individually comprise the transistor material and the first capacitor electrode material. Capacitors are formed that individually comprise the first capacitor electrode material of individual of the pillars. Vertical transistors are formed above the capacitors that individually comprise the transistor material of the individual pillars. Other aspects and embodiments are disclosed, including structure independent of method.

Memory devices including vertical transistors and methods of forming such memory devices are disclosed. An example memory device includes a substrate, a BL in the substrate, a channel region over a portion of the BL, a second region over the channel region, an insulator wrapped around at least a portion of the channel region, and a WL. The BL also operates as one of a source region and a drain region of the transistor. The second region is the other one of the source region and the drain region. The WL wraps around at least a portion of the insulator and is separated from the channel region by the insulator. In some embodiments, the BL is formed in a trench in the substrate. An aspect ratio of the BL is in a range from 0.5 to 10. The BL may have a higher conductivity than the channel region.

A method of forming an array of capacitors comprises forming a vertical stack above a substrate. The stack comprises a horizontally-elongated conductive structure and an insulator material directly above the conductive structure. Horizontally-spaced openings are formed in the insulator material to the conductive structure. An upwardly-open container-shaped bottom capacitor electrode is formed in individual of the openings. The bottom capacitor electrode is directly against conductive material of the conductive structure. The conductive structure directly electrically couples the bottom capacitor electrodes together. A capacitor insulator is formed in the openings laterally-inward of the bottom capacitor electrodes. A top capacitor electrode is formed in individual of the openings laterally-inward of the capacitor insulator. The top capacitor electrodes are not directly electrically coupled together. Structure independent of method is disclosed.

Technologies for fabricating a vertical dynamic random access memory (DRAM) structure include forming a DRAM cell hole through a word line layer and an associated substrate such that a first section of the DRAM cell hole extends through the word line layer and a second section of the DRAM cell hole extends through the substrate in vertical alignment with the first section. A pillar capacitor structure is initially formed using the second section of the DRAM cell hole, followed by the formation of a transistor using the first section of the DRAM cell hole as a channel for the transistor. Due to the use of a common DRAM cell hole, the pillar capacitor structure and the channel are in vertical alignment. The substrate is subsequently flipped and removed from the pillar capacitor structure, which is further processed to form a pillar capacitor. In some embodiments, the channel may be formed from a deposition of indium gallium zinc oxide (IGZO).

Provided are a semiconductor structure and a method for manufacturing the same, a memory device and a method for manufacturing the same. The semiconductor structure includes at least one transistor. Each of the at least one transistor includes a channel including a first semiconductor layer and a second semiconductor layer disposed around the first semiconductor layer. The second semiconductor layer introduces strain into the channel.

A method used in forming an array of memory cells comprises forming a vertical stack comprising transistor material directly above insulator material. A mask is used to subtractively etch both the transistor material and thereafter the insulator material to form a plurality of pillars that individually comprise the transistor material and the insulator material. The insulator material is laterally-recessed from opposing lateral sides of individual of the pillars selectively relative to the transistor material of the individual pillars. The individual pillars are formed to comprise a first capacitor electrode that is in void space formed from the laterally recessing. Capacitors are formed that individually comprise the first capacitor electrode of the individual pillars. A capacitor insulator is aside the first capacitor electrode of the individual pillars and a second capacitor electrode is laterally-outward of the capacitor insulator. Vertical transistors are formed above the capacitors and individually comprise the transistor material of the individual pillars. Other aspects, including structure independent of method, are disclosed.

A capacitive element is located in an active region of the substrate and on a front face of the substrate. The capacitive element includes a first electrode and a second electrode. The first electrode is formed by a first conductive region and the active region. The second electrode is formed by a second conductive region and a monolithic conductive region having one part covering a surface of said front face and at least one part extending into the active region perpendicularly to said front face. The first conductive region is located between and is insulated from the monolithic conductive region and a second conductive region.