Systems, methods, and apparatuses are provided for self-aligned etch back for vertical three dimensional (3D) memory. One example method includes depositing layers of a first dielectric material, a semiconductor material, and a second dielectric material to form a vertical stack, forming first vertical openings to form elongated vertical, pillar columns with first vertical sidewalls in the vertical stack, and forming second vertical openings through the vertical stack to expose second vertical sidewalls. Further, the example method includes removing portions of the semiconductor material to form first horizontal openings and depositing a fill in the first horizontal openings. The method can further include forming third vertical openings to expose third vertical sidewalls in the vertical stack and selectively removing the fill material to form a plurality of second horizontal openings in which to form horizontally oriented storage nodes.

A method of forming an array of capacitors and access transistors there-above comprises forming access transistor trenches partially into insulative material. The trenches individually comprise longitudinally-spaced masked portions and longitudinally-spaced openings in the trenches longitudinally between the masked portions. The trench openings have walls therein extending longitudinally in and along the individual trench openings against laterally-opposing sides of the trenches. At least some of the insulative material that is under the trench openings is removed through bases of the trench openings between the walls and the masked portions to form individual capacitor openings in the insulative material that is lower than the walls. Individual capacitors are formed in the individual capacitor openings. A line of access transistors is formed in the individual trenches. The line of access transistors electrically couples to the individual capacitors that are along that line. Other aspects, including structure independent of method, are disclosed.

A method of forming a tier of an array of memory cells within an array area, the memory cells individually comprising a capacitor and an elevationally-extending transistor, the method comprising using two, and only two, sacrificial masking steps within the array area of the tier in forming the memory cells. Other methods are disclosed, as are structures independent of method of fabrication.

A memory cell arrangement is provided that may include: a plurality of electrode layers, wherein each of the plurality of electrode layers comprises a plurality of through holes, each of the plurality of through holes extending from a first surface to a second surface of a respective electrode layer; a plurality of electrode pillars, wherein each of the plurality of electrode pillars comprises a plurality of electrode portions, wherein each of the plurality of electrode portions is disposed within a corresponding one of the plurality of through holes; wherein the respective electrode layer and a respective electrode portion of the plurality of electrode portions form a first electrode and a second electrode of a capacitor and wherein at least one memory material portion is disposed in each of the plurality of through holes in a gap between the respective electrode layer and the respective electrode portion.

Some embodiments include an integrated assembly. The integrated assembly has a first transistor with a horizontally-extending channel region between a first source/drain region and a second source/drain region; has a second transistor with a vertically-extending channel region between a third source/drain region and a fourth source/drain region; and has a capacitor between the first and second transistors. The capacitor has a first electrode, a second electrode, and an insulative material between the first and second electrodes. The first electrode is electrically connected with the first source/drain region, and the second electrode is electrically connected with the third source/drain region. A digit line is electrically connected with the second source/drain region. A conductive structure is electrically connected with the fourth source/drain region.

A method of forming a vertical transistor comprising a top source/drain region, a bottom source/drain region, a channel region vertically between the top and bottom source/drain regions, and a gate operatively laterally-adjacent the channel region comprises, in multiple time-spaced microwave annealing steps, microwave annealing at least the channel region. The multiple time-spaced microwave annealing steps reduce average concentration of elemental-form H in the channel region from what it was before start of the multiple time-spaced microwave annealing steps. The reduced average concentration of elemental-form H is 0.005 to less than 1 atomic percent. Structure embodiments are disclosed.

Some embodiments include integrated memory. The integrated memory includes a first series of first conductive structures and a second series of conductive structures. The first conductive structures extend along a first direction. The second conductive structures extend along a second direction which crosses the first direction. Pillars of semiconductor material extend upwardly from the first conductive structures. Each of the pillars includes a lower source/drain region, an upper source/drain region, and a channel region between the lower and upper source/drain regions. The lower source/drain regions are coupled with the first conductive structures. Insulative material is adjacent sidewall surfaces of the pillars. The insulative material includes ZrO.sub.x, where x is a number greater than 0. The second conductive structures include gating regions which are spaced from the channel regions by at least the insulative material. Storage elements are coupled with the upper source/drain regions.

Methods, systems, and devices for dimension control for raised lines are described. For example, the techniques described herein may be used to fabricate raised lines (e.g., orthogonal raised lines). The lines may be fabricated such that an overall area of each line is consistent. In some examples, the techniques may be applied to form memory cells across multiple memory tiles, multiple memory arrays, and/or multiple wafers such that each memory cell comprises a consistent overall area. To form the lines and/or memory cells, a material associated with a desired properties may be deposited after performing a first cut. Due to the properties associated with the material, a width of the second cut may be affected, thus resulting in more uniform lines and/memory cells.

Apparatuses, systems, and methods for ferroelectric memory (FeRAM) cell operation. An FeRAM cell may have different charge regions it can operate across. Some regions, such as dielectric regions, may operate faster, but with reduced signal on a coupled digit line. To improve the performance while maintaining increased speed, two digit lines may be coupled to the same sense amplifier, so that the FeRAM cells coupled to both digit lines contribute signal to the sense amplifier. For example a first digit line in a first deck of the memory and a second digit line in a second deck of the memory may both be coupled to the sense amplifier. In some embodiments, additional digit lines may be used as shields (e.g., by coupling the shield digit lines to a ground voltage) to further improve the signal-to-noise ratio.

Provided is an electronic device including a semiconductor memory. The semiconductor memory may include: a vertical electrode formed over a substrate; a plurality of first memory elements and a plurality of first interlayer dielectric layers alternately stacked along a first side surface of the vertical electrode; and a plurality of second memory elements and a plurality of second interlayer dielectric layers alternately stacked along a second side surface of the vertical electrode, and the plurality of first memory elements correspond to the plurality of second interlayer dielectric layers, respectively, in the vertical direction.