Abstract: In an example, a wet cleaning process is performed to clean a structure having features and openings between the features while preventing drying of the structure. After performing the wet cleaning process, a polymer solution is deposited in the openings while continuing to prevent any drying of the structure. A sacrificial polymer material is formed in the openings from the polymer solution. The structure may be used in semiconductor devices, such as integrated circuits, memory devices, MEMS, among others.

Abstract: Methods include exposing polysilicon to an aqueous composition comprising nitric acid, poly-carboxylic acid and ammonium fluoride, and removing a portion of the polysilicon selective to an oxide using the aqueous composition.

Abstract: In an example, a wet cleaning process is performed to clean a structure having features and openings between the features while preventing drying of the structure. After performing the wet cleaning process, a polymer solution is deposited in the openings while continuing to prevent any drying of the structure. A sacrificial polymer material is formed in the openings from the polymer solution. The structure may be used in semiconductor devices, such as integrated circuits, memory devices, MEMS, among others.

Abstract: Methods include exposing polysilicon to an aqueous composition comprising nitric acid, poly-carboxylic acid and ammonium fluoride, and removing a portion of the polysilicon selective to an oxide using the aqueous composition.

Abstract: Methods include exposing polysilicon to an aqueous composition comprising nitric acid, poly-carboxylic acid and ammonium fluoride, and removing a portion of the polysilicon selective to an oxide using the aqueous composition.

Abstract: Methods include exposing polysilicon to an aqueous composition comprising nitric acid, poly-carboxylic acid and ammonium fluoride, and removing a portion of the polysilicon selective to an oxide using the aqueous composition.

Abstract: Compositions for etching polysilicon including aqueous compositions containing nitric acid, ammonium fluoride, and poly-carboxylic acid.

Abstract: A surface modification composition comprising a silylation agent comprising a silyl acetamide, a silylation catalyst comprising a perfluoro acid anhydride, an amine-based complexing agent, and an organic solvent. Methods of modifying a silicon-based material and methods of forming high aspect ratio structures on a substrate are also disclosed.

Abstract: Methods of selectively forming a metal-doped chalcogenide material comprise exposing a chalcogenide material to a transition metal solution, and incorporating transition metal of the transition solution into the chalcogenide material without substantially incorporating the transition metal into an adjacent material. The chalcogenide material is not silver selenide. Another method comprises forming a chalcogenide material adjacent to and in contact with an insulative material, exposing the chalcogenide material and the insulative material to a transition metal solution, and diffusing transition metal of the transition metal solution into the chalcogenide material while substantially no transition metal diffuses into the insulative material.

Abstract: Compositions for removing residues from a semiconductor structure. The compositions comprise water, a base, a polydentate chelator, a degasser, and a fluorine source. The compositions comprise greater than or equal to approximately 99 wt % of the water and are formulated to exhibit a pH of from approximately 10.0 to approximately 12.0. Methods of forming and using the compositions are also disclosed.

Abstract: Compositions for removing residues from a semiconductor structure. The compositions comprise water, a base, a polydentate chelator, a degasser, and a fluorine source. The compositions comprise greater than or equal to approximately 99 wt % of the water and are formulated to exhibit a pH of from approximately 10.0 to approximately 12.0. Methods of forming and using the compositions are also disclosed.

Abstract: Some embodiments include methods of forming memory cells. Chalcogenide is formed over a plurality of bottom electrodes, and top electrode material is formed over the chalcogenide. Sacrificial material is formed over the top electrode material. A plurality of memory cell structures is formed by etching through the sacrificial material, top electrode material and chalcogenide. Each of the memory cell structures has a cap of the sacrificial material thereover. The etching forms polymeric residue over the sacrificial material caps, and damages chalcogenide along sidewalls of the structures. The sacrificial material is removed with an HF-containing solution, and such removes the polymeric residue off of the memory cell structures. After the sacrificial material is removed, the sidewalls of the structures are treated with one or both of H2O2 and HNO3 to remove damaged chalcogenide from the sidewalls of the memory cell structures.

Abstract: Compositions for etching polysilicon including aqueous compositions containing nitric acid and ammonium fluoride.

Abstract: Methods of selectively forming a metal-doped chalcogenide material comprise exposing a chalcogenide material to a transition metal solution, and incorporating transition metal of the transition solution into the chalcogenide material without substantially incorporating the transition metal into an adjacent material. The chalcogenide material is not silver selenide. Another method comprises forming a chalcogenide material adjacent to and in contact with an insulative material, exposing the chalcogenide material and the insulative material to a transition metal solution, and diffusing transition metal of the transition metal solution into the chalcogenide material while substantially no transition metal diffuses into the insulative material.

Abstract: Methods and compositions for etching polysilicon including aqueous compositions containing nitric acid and ammonium fluoride, and apparatus formed thereby.

Abstract: Methods of selectively forming a metal-doped chalcogenide material comprise exposing a chalcogenide material to a transition metal solution, and incorporating transition metal of the transition solution into the chalcogenide material without substantially incorporating the transition metal into an adjacent material. The chalcogenide material is not silver selenide. Another method comprises forming a chalcogenide material adjacent to and in contact with an insulative material, exposing the chalcogenide material and the insulative material to a transition metal solution, and diffusing transition metal of the transition metal solution into the chalcogenide material while substantially no transition metal diffuses into the insulative material.

Abstract: Methods and compositions for etching polysilicon including aqueous compositions containing nitric acid and ammonium fluoride, and apparatus formed thereby.

Abstract: Some embodiments include a memory device and a method of forming the memory device. One such memory device includes a string of stacked memory cells. Each of the memory cells in the string includes a charge storage structure and a recessed control gate. The recessed control gate has a substantially smooth surface separated from the charge storage structure by dielectric material. One such method includes etching heavily boron doped polysilicon selective to oxide to form a recessed control gate having a surface with nubs. A smoothing solution is applied to the surface of the recessed control gate to smoothen the nubs. Additional apparatuses and methods are described.

Abstract: Some embodiments include methods of forming memory cells. Chalcogenide is formed over a plurality of bottom electrodes, and top electrode material is formed over the chalcogenide. Sacrificial material is formed over the top electrode material. A plurality of memory cell structures is formed by etching through the sacrificial material, top electrode material and chalcogenide. Each of the memory cell structures has a cap of the sacrificial material thereover. The etching forms polymeric residue over the sacrificial material caps, and damages chalcogenide along sidewalls of the structures. The sacrificial material is removed with an HF-containing solution, and such removes the polymeric residue off of the memory cell structures. After the sacrificial material is removed, the sidewalls of the structures are treated with one or both of H2O2 and HNO3 to remove damaged chalcogenide from the sidewalls of the memory cell structures.

Abstract: Methods of selectively forming a metal-doped chalcogenide material comprise exposing a chalcogenide material to a transition metal solution, and incorporating transition metal of the transition solution into the chalcogenide material without substantially incorporating the transition metal into an adjacent material. The chalcogenide material is not silver selenide. Another method comprises forming a chalcogenide material adjacent to and in contact with an insulative material, exposing the chalcogenide material and the insulative material to a transition metal solution, and diffusing transition metal of the transition metal solution into the chalcogenide material while substantially no transition metal diffuses into the insulative material.