Some embodiments include a memory cell having charge-trapping-material between a semiconductor channel material and a gating region. The charge-trapping-material includes silicon, nitrogen and trap-enhancing-additive. The trap-enhancing-additive includes one or more of carbon, phosphorus, boron and metal. Some embodiments include an integrated assembly having a stack of alternating first and second levels. The first levels include conductive structures and the second levels are insulative. Channel-material-pillars extend through the stack. Charge-trapping-regions are along the channel-material-pillars and are between the channel-material-pillars and the conductive structures. The charge-trapping-regions include a charge-trapping-material which contains silicon, nitrogen and trap-enhancing-additive. The trap-enhancing-additive includes one or more of carbon, phosphorus, boron and metal.

Some embodiments include a memory cell having charge-trapping-material between a semiconductor channel material and a gating region. The charge-trapping-material includes silicon, nitrogen and trap-enhancing-additive. The trap-enhancing-additive includes one or more of carbon, phosphorus, boron and metal. Some embodiments include an integrated assembly having a stack of alternating first and second levels. The first levels include conductive structures and the second levels are insulative. Channel-material-pillars extend through the stack. Charge-trapping-regions are along the channel-material-pillars and are between the channel-material-pillars and the conductive structures. The charge-trapping-regions include a charge-trapping-material which contains silicon, nitrogen and trap-enhancing-additive. The trap-enhancing-additive includes one or more of carbon, phosphorus, boron and metal.

Some embodiments include an integrated assembly having a source structure, and having a stack of alternating conductive levels and insulative levels over the source structure. Cell-material-pillars pass through the stack. The cell-material-pillars are arranged within a configuration which includes a first memory-block-region and a second memory-block-region. The cell-material-pillars include channel material which is electrically coupled with the source structure. Memory cells are along the conductive levels and include regions of the cell-material-pillars. A panel is between the first and second memory-block-regions. The panel has a first material configured as a container shape. The container shape defines opposing sides and a bottom of a cavity. The panel has a second material within the cavity. The second material is compositionally different from the first material. Some embodiments include methods of forming integrated assemblies.

Some embodiments include an integrated assembly having a source structure, and having a stack of alternating conductive levels and insulative levels over the source structure. Cell-material-pillars pass through the stack. The cell-material-pillars are arranged within a configuration which includes a first memory-block-region and a second memory-block-region. The cell-material-pillars include channel material which is electrically coupled with the source structure. Memory cells are along the conductive levels and include regions of the cell-material-pillars. A panel is between the first and second memory-block-regions. The panel has a first material configured as a container shape. The container shape defines opposing sides and a bottom of a cavity. The panel has a second material within the cavity. The second material is compositionally different from the first material. Some embodiments include methods of forming integrated assemblies.

The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a source/drain region arranged within a substrate. A first select gate is arranged over the substrate, and a first memory gate is arranged over the substrate and separated from the source/drain region by the first select gate. An inter-gate dielectric structure is arranged between the first memory gate and the first select gate. The inter-gate dielectric structure extends under the first memory gate. A height of the inter-gate dielectric structure decreases along a direction extending from the first select gate to the first memory gate.

Systems, apparatuses, and methods may provide for technology for forming extended air gaps for bitline contacts. For example, such technology patterns and etches a dielectric layer and a bitline layer to create bitline contacts in a memory die. An air gap dielectric layer is deposited to form an air gap between adjacent bitline contacts, and wherein the air gap has a height dimension that extends past a height dimension of the bitline contacts.

Disclosed is a semiconductor memory device including a substrate, a plurality of source lines extending in a first direction on the substrate, a plurality of word lines crossing the source lines and extending in a second direction different from the first direction, a plurality of bit lines crossing the source lines and the word lines and extending in a third direction different from the first direction and the second direction, and a plurality of memory cells disposed at intersections between the source lines, the word lines, and the bit lines. The first, second, and third directions are parallel to a top surface of the substrate.

A method of forming a semiconductor device comprises forming sacrificial structures and support pillars on a material. Tiers are formed over the sacrificial structures and support pillars and tier pillars and tier openings are formed to expose the sacrificial structures. One or more of the tier openings comprises a greater critical dimension than the other tier openings. The sacrificial structures are removed to form a cavity. A cell film is formed over sidewalls of the tier pillars, the cavity, and the one or more tier openings. A fill material is formed in the tier openings and adjacent to the cell film and a portion removed from the other tier openings to form recesses adjacent to an uppermost tier. Substantially all of the fill material is removed from the one or more tier openings. A doped polysilicon material is formed in the recesses and the one or more tier openings. A conductive material is formed in the recesses and in the one or more tier openings. An opening is formed in a slit region and a dielectric material is formed in the opening. Additional methods, semiconductor devices, and systems are disclosed.

A semiconductor memory device that may include a substrate, an array of memory cells arranged in rows and columns, bit lines and word lines. The memory cells each may include a pillar-shaped active region extending vertically, which includes source/drain regions at upper and lower ends respectively and a channel region between the source/drain regions. The channel region may include a single-crystalline semiconductor material. The memory cells each may further include a gate stack formed around a periphery of the channel region. Each of the bit lines is located below a corresponding column, and electrically connected to the lower source/drain regions of the respective memory cells in the corresponding column. Each of the word lines is electrically connected to the gate stacks of the respective memory cells in a corresponding row.

A vertical memory device includes a substrate having a peripheral circuit interconnection, lower word lines stacked on the substrate, vertical channel structures passing through the lower word lines, a first cell contact plug including a bottom end lower than a bottom surface of a first lower word line and being connected to the first lower word line, and lower insulating layers and first lower mold patterns positioned beneath the first lower word line and stacked alternately on each other from the substrate.