A process of smoothing a top surface of a bit line metal of a memory structure decreases resistance of a bit line stack. The process includes depositing a titanium layer of approximately 30 angstroms to 50 angstroms on a polysilicon layer on a substrate, depositing a first titanium nitride layer of approximately 15 angstroms to approximately 40 angstroms on the titanium layer, annealing the substrate at a temperature of approximately 700 degrees Celsius to approximately 850 degrees Celsius, depositing a second titanium nitride layer of approximately 15 angstroms to approximately 40 angstroms on the first titanium nitride layer after annealing, and depositing a bit line metal layer of ruthenium on the second titanium nitride layer.

Some embodiments include an integrated assembly which has digit-line-contact-regions laterally spaced from one another by intervening regions. Non-conductive-semiconductor-material is over the intervening regions. Openings extend through the non-conductive-semiconductor-material to the digit-line-contact-regions. Conductive-semiconductor-material-interconnects are within the openings and are coupled with the digit-line-contact-regions. Upper surfaces of the conductive-semiconductor-material-interconnects are beneath a lower surface of the non-conductive-semiconductor-material. Metal-containing-digit-lines are over the non-conductive-semiconductor-material. Conductive regions extend downwardly from the metal-containing-digit-lines to couple with the conductive-semiconductor-material-interconnects. Some embodiments include methods of forming integrated assemblies.

A method of forming a plurality of conductive vias comprises forming spaced contact openings individually having two opposing sidewalls comprising Si.sub.wB.sub.xO.sub.yN.sub.z, where w is from 0.1 to 0.3, x is from 0.1 to 0.4, y is from 0 to 0.2, and z is from 0.4 to 0.6. A lining comprising silicon nitride is formed over the two opposing sidewalls in individual of the contact openings. A conductive via is formed in the individual contact openings over the lining. Integrated circuitry is disclosed.

A memory array comprises vertically-alternating tiers of insulative material and memory cells. The memory cells individually include a transistor comprising first and second source/drain regions having a channel region there-between and a gate operatively proximate the channel region. At least a portion of the channel region is horizontally-oriented for horizontal current flow in the portion between the first and second source/drain regions. The memory cells individually include a capacitor comprising first and second electrodes having a capacitor insulator there-between. The first electrode is electrically coupled to the first source/drain region. The second capacitor electrodes of multiple of the capacitors in the array are electrically coupled with one another. A sense-line structure extends elevationally through the vertically-alternating tiers. Individual of the second source/drain regions of individual of the transistors that are in different memory cell tiers are electrically coupled to the elevationally-extending sense-line structure. Additional embodiments are disclosed.

A method of forming a plurality of conductive vias comprises forming spaced contact openings individually having two opposing sidewalls comprising Si.sub.wB.sub.xO.sub.yN.sub.z, where w is from 0.1 to 0.3, x is from 0.1 to 0.4, y is from 0 to 0.2, and z is from 0.4 to 0.6. A lining comprising silicon nitride is formed over the two opposing sidewalls in individual of the contact openings. A conductive via is formed in the individual contact openings over the lining. Integrated circuitry is disclosed.

A method of forming an elevationally-extending conductor laterally between a pair of structures comprises forming a pair of structures individually comprising an elevationally-extending-conductive via and a conductive line electrically coupled to and crossing above the conductive via. The conductive line and the conductive via respectively have opposing sides in a vertical cross-section. Elevationally-extending-insulative material is formed along the opposing sides of the conductive via and the conductive line in the vertical cross-section. The forming of the insulative material comprises forming a laterally-inner-insulator material comprising silicon, oxygen, and carbon laterally-outward of the opposing sides of the conductive via and the conductive line in the vertical cross-section. A laterally-intervening-insulator material comprising silicon and oxygen is formed laterally-outward of opposing sides of the laterally-inner-insulator material in the vertical cross-section. The laterally-intervening-insulator material comprises less carbon, if any, than the laterally-inner-insulator material. A laterally-outer-insulator material comprising silicon, oxygen, and carbon is formed laterally-outward of opposing sides of the laterally-intervening-insulator material in the vertical cross-section. The laterally-outer-insulator material comprises more carbon than the laterally-inner-insulator material. Elevationally-extending-conductor material is formed laterally between and along the insulative material in the vertical cross-section. Additional method aspects, including structure independent of method of fabrication, are disclosed.

A semiconductor structure includes: a substrate; a stacked structure, contact structures, and storage nodes. The stacked structure is located on the substrate and includes semiconductor layers extending in a first direction and arranged in a spaced manner in a second direction and in a third direction, wherein the first direction and the second direction are directions parallel to a plane where the substrate is located, the first direction is perpendicular to the second direction, and the third direction is a direction perpendicular to the plane where the substrate is located. The contact structures include a first end and a second end in the first direction, wherein the first ends of the contact structures are connected to the semiconductor layers, and a material of the contact structures includes metal silicide. The storage nodes extend in the first direction and are connected to a second end of respective contact structures.

Some embodiments include an integrated assembly which has digit-line-contact-regions laterally spaced from one another by intervening regions. Non-conductive-semiconductor-material is over the intervening regions. Openings extend through the non-conductive-semiconductor-material to the digit-line-contact-regions. Conductive-semiconductor-material-interconnects are within the openings and are coupled with the digit-line-contact-regions. Upper surfaces of the conductive-semiconductor-material-interconnects are beneath a lower surface of the non-conductive-semiconductor-material. Metal-containing-digit-lines are over the non-conductive-semiconductor-material. Conductive regions extend downwardly from the metal-containing-digit-lines to couple with the conductive-semiconductor-material-interconnects. Some embodiments include methods of forming integrated assemblies.

Some embodiments relate to a memory device including first and second conductive lines extending generally in parallel with one another within over a row of memory cells. A centerline extends generally in parallel with the first and second conductive lines and is spaced between the first and second conductive lines. A first plurality of conductive line segments is over the first conductive line. Conductive line segments of the first plurality of conductive line segments are coupled to different locations on the first conductive line. A second plurality of conductive line segments are disposed over the second conductive line, and are coupled to different locations on the second conductive line.

Some embodiments include an integrated assembly which has digit-line-contact-regions laterally spaced from one another by intervening regions. Non-conductive-semiconductor-material is over the intervening regions. Openings extend through the non-conductive-semiconductor-material to the digit-line-contact-regions. Conductive-semiconductor-material-interconnects are within the openings and are coupled with the digit-line-contact-regions. Upper surfaces of the conductive-semiconductor-material-interconnects are beneath a lower surface of the non-conductive-semiconductor-material. Metal-containing-digit-lines are over the non-conductive-semiconductor-material. Conductive regions extend downwardly from the metal-containing-digit-lines to couple with the conductive-semiconductor-material-interconnects. Some embodiments include methods of forming integrated assemblies.