Some embodiments include a method of forming an integrated assembly. A construction is formed to include a structure having an exposed surface, and to include an opening proximate the structure. An aperture extends into the opening. A first material is deposited to form a mass along the exposed surface of the structure. Particles are sputtered from the mass and across the aperture. The particles agglomerate to form a sealant material which traps a void within the opening.

Systems, methods and apparatus are provided for an array of vertically stacked memory cells having horizontally oriented access devices and storage nodes. The horizontally oriented access devices having a first source/drain regions and a second source drain regions separated by silicon (Si) channel regions. A digit line having a global digit line (GDL) contact is formed in a trench adjacent to the first source/drain regions. In one example, the digit line is electrically isolated from a neighboring digit line at the bottom of the trench. In another example, the digit line is formed continuously along a bottom surface of trench to form shared digit lines between horizontal access devices, in two separate arrays, on opposing second vertical surfaces. The memory cells have horizontally oriented storage nodes coupled to the second source/drain regions and vertical digit lines coupled to the first source/drain regions.

Systems, methods and apparatus are provided for an array of vertically stacked memory cells. The vertically stacked memory cells have horizontally oriented access devices having a first source/drain region, a channel region, and a second source drain and horizontally oriented storage nodes that are vertically separated from the access devices. Horizontally oriented access lines are coupled to gates, separated from the respective channel regions by gate dielectrics, and vertically oriented digit lines are coupled to respective first source/drain regions. The horizontally oriented storage nodes each have a first electrode coupled to the second source/drain regions of the access devices and each first electrode opposes two different sides of the horizontal access devices including an electrical contact with a vertical side of the second source/drain regions.

According to one embodiment, a semiconductor device includes a semiconductor substrate and a capacitor that includes a first electrode extending in a first direction intersecting the semiconductor substrate and a second electrode facing the first electrode. A first conductive layer is above the capacitor and extends in a second direction. A semiconductor layer penetrates the first conductive layer in the first direction. A first conductor can be above or below the first conductive layer and electrically connected to the first conductive layer. A first insulating film is between the first conductive layer and the semiconductor layer. A second conductive layer extends in the second direction and is electrically connected to the first conductive layer via the first conductor.

The memory capacity of a DRAM is enhanced. A semiconductor memory device includes a driver circuit including part of a single crystal semiconductor substrate, a multilayer wiring layer provided over the driver circuit, and a memory cell array layer provided over the multilayer wiring layer. That is, the memory cell array overlaps with the driver circuit. Accordingly, the integration degree of the semiconductor memory device can be increased as compared to the case where a driver circuit and a memory cell array are provided in the same plane of a substrate containing a singe crystal semiconductor material.

A semiconductor device includes an insulating base including a trench, a transistor including a gate electrode and vertical channel in the trench, and a source electrode in the insulating base outside the trench, an isolation layer on the gate electrode in the trench, and a capacitor including a trench capacitor portion that is on the isolation layer in the trench, and a stacked capacitor portion that is coupled to the source electrode of the transistor outside the trench.

A semiconductor device includes an insulating base including a trench, a transistor including a gate electrode and vertical channel in the trench, and a source electrode in the insulating base outside the trench, an isolation layer on the gate electrode in the trench, and a capacitor including a trench capacitor portion that is on the isolation layer in the trench, and a stacked capacitor portion that is coupled to the source electrode of the transistor outside the trench.

A configuration for efficiently placing a group of capacitors with one terminal connected to a common node is described. The capacitors are stacked and folded along the common node. In a stack and fold configuration, devices are stacked vertically (directly or with a horizontal offset) with one terminal of the devices being shared to a common node, and further the capacitors are placed along both sides of the common node. The common node is a point of fold. In one example, the devices are capacitors. N number of capacitors can be divided in L number of stack layers such that there are N/L capacitors in each stacked layer. The N/L capacitors are shorted together with an electrode (e.g., bottom electrode). The electrode can be metal, a conducting oxide, or a combination of a conducting oxide and a barrier material. The capacitors can be planar, non-planar or replaced by memory elements.

A volatile memory device can include a bit line structure having a vertical side wall. A lower spacer can be on a lower portion of the vertical side wall, where the lower spacer can be defined by a first thickness from the vertical side wall to an outer side wall of the lower spacer. An upper spacer can be on an upper portion of the vertical side wall above the lower portion, where the upper spacer can be defined by a second thickness that is less than the first thickness, the upper spacer exposing an uppermost portion of the outer side wall of the lower spacer.

The present disclosure provides a method for preparing a semiconductor memory structure. The method includes the following steps: providing a substrate comprising a plurality of active regions extending in a first direction; forming a plurality of first trenches in the substrate, the first trenches comprising a first depth and extending in a second direction different from the first direction; forming a plurality of buried digit lines in the first trenches; forming a plurality of second trenches in the substrate, the second trenches comprising a second depth and extending in a third direction different from the first direction and the second direction; deepening portions of the second trenches to form a plurality of third trenches in the substrate, the third trenches comprising a third depth; and forming a plurality of buried word lines in the third trenches.