Abstract: A DRAM capacitor comprising a first capacitor electrode configured as a container and comprising a doped titanium nitride material, a capacitor dielectric on the first capacitor electrode, and a second capacitor electrode on the capacitor dielectric. Methods of forming the DRAM capacitor are also disclosed, as are semiconductor devices and systems comprising such DRAM capacitors.

Abstract: A DRAM capacitor comprising a first capacitor electrode configured as a container and comprising a doped titanium nitride material, a capacitor dielectric on the first capacitor electrode, and a second capacitor electrode on the capacitor dielectric. Methods of forming the DRAM capacitor are also disclosed, as are semiconductor devices and systems comprising such DRAM capacitors.

Abstract: A DRAM capacitor comprising a first capacitor electrode configured as a container and comprising a doped titanium nitride material, a capacitor dielectric on the first capacitor electrode, and a second capacitor electrode on the capacitor dielectric. Methods of forming the DRAM capacitor are also disclosed, as are semiconductor devices and systems comprising such DRAM capacitors.

Abstract: A semiconductor structure may include a first electrode over a substrate, a high-K dielectric material over the first electrode, and a second electrode over the high-K dielectric material, wherein at least one of the first electrode and the second electrode may include a material selected from the group consisting of a molybdenum nitride (MoaNb) material, a molybdenum oxynitride (MoOxNy) material, a molybdenum oxide (MoOx) material, and a molybdenum-based alloy material comprising molybdenum and nitrogen.

Abstract: Methods of forming a capacitor including forming a titanium nitride material within at least one aperture defined by a support material, forming a ruthenium material within the at least one aperture over the titanium nitride material, and forming a first conductive material over the ruthenium material within the at least one aperture. The titanium nitride material may be oxidized to a titanium dioxide material. A second conductive material may be formed over a surface of the titanium dioxide material. A semiconductor device may include at least one capacitor, wherein a major longitudinal portion of the at least one capacitor is not surrounded by a solid material. The capacitor may include a first electrode; a ruthenium oxide material laterally adjacent the first electrode; a rutile titanium dioxide material laterally adjacent the ruthenium oxide material; and a second electrode laterally adjacent the rutile titanium dioxide material.

Abstract: A method of forming a capacitor includes depositing a dielectric metal oxide layer of a first phase to a thickness no greater than 75 Angstroms over an inner conductive capacitor electrode material. The first phase dielectric metal oxide layer has a k of at least 15. Conductive RuO2 is deposited over and into physical contact with the dielectric metal oxide layer. Then, the RuO2 and the dielectric metal oxide layer are annealed at a temperature below 500° C. The RuO2 in physical contact with the dielectric metal oxide during the annealing facilitates a change of the dielectric metal oxide layer from the first phase to a second crystalline phase having a higher k than the first phase. The annealed dielectric metal oxide layer is incorporated into a capacitor dielectric region of a capacitor construction. Other implementations are disclosed.

Abstract: Methods of forming an insulative element are described, including forming a first metal oxide material having a first dielectric constant, forming a second metal oxide material having a second dielectric constant different from the first, and heating at least portions of the structure to crystallize at least a portion of at least one of the first dielectric material and the second dielectric material. Methods of forming a capacitor are described, including forming a first electrode, forming a dielectric material with a first oxide and a second oxide over the first electrode, and forming a second electrode over the dielectric material. Structures including dielectric materials are also described.

Abstract: A semiconductor structure may include a first electrode over a substrate, a high-K dielectric material over the first electrode, and a second electrode over the high-K dielectric material, wherein at least one of the first electrode and the second electrode may include a material selected from the group consisting of a molybdenum nitride (MoxNy) material, a molybdenum oxynitride (MoOxNy) material, a molybdenum oxide (MoOx) material, and a molybdenum-based alloy material comprising molybdenum and nitrogen.

Abstract: Methods of forming a capacitor including forming a titanium nitride material within at least one aperture defined by a support material, forming a ruthenium material within the at least one aperture over the titanium nitride material, and forming a first conductive material over the ruthenium material within the at least one aperture. The titanium nitride material may be oxidized to a titanium dioxide material. A second conductive material may be formed over a surface of the titanium dioxide material. A semiconductor device may include at least one capacitor, wherein a major longitudinal portion of the at least one capacitor is not surrounded by a solid material. The capacitor may include a first electrode; a ruthenium oxide material laterally adjacent the first electrode; a rutile titanium dioxide material laterally adjacent the ruthenium oxide material; and a second electrode laterally adjacent the rutile titanium dioxide material.

Abstract: Methods of forming an insulative element are described, including forming a first metal oxide material having a first dielectric constant, forming a second metal oxide material having a second dielectric constant different from the first, and heating at least portions of the structure to crystallize at least a portion of at least one of the first dielectric material and the second dielectric material. Methods of forming a capacitor are described, including forming a first electrode, forming a dielectric material with a first oxide and a second oxide over the first electrode, and forming a second electrode over the dielectric material. Structures including dielectric materials are also described.

Abstract: Methods of forming a capacitor including forming a titanium nitride material within at least one aperture defined by a support material, forming a ruthenium material within the at least one aperture over the titanium nitride material, and forming a first conductive material over the ruthenium material within the at least one aperture. The titanium nitride material may be oxidized to a titanium dioxide material. A second conductive material may be formed over a surface of the titanium dioxide material. A semiconductor device may include at least one capacitor, wherein a major longitudinal portion of the at least one capacitor is not surrounded by a solid material. The capacitor may include a first electrode; a ruthenium oxide material laterally adjacent the first electrode; a rutile titanium dioxide material laterally adjacent the ruthenium oxide material; and a second electrode laterally adjacent the rutile titanium dioxide material.

Abstract: Methods of forming rutile titanium dioxide comprise exposing a transition metal (such as V, Cr, W, Mn, Ru, Os, Rh, Ir, Pt, Ge, Sn, or Pb) to an atmosphere consisting of oxygen gas (O2) to produce an oxidized transition metal over an unoxidized portion of the transition metal. Rutile titanium dioxide is formed over the oxidized transition metal by atomic layer deposition. The oxidized transition metal is sequentially exposed to a titanium halide precursor and an oxidizer. Other methods include oxidizing a portion of a ruthenium material to ruthenium(IV) oxide using an atmosphere consisting of O2, nitric oxide (NO), or nitrous oxide (N2O); and introducing a gaseous titanium halide precursor and water vapor to the ruthenium(IV) oxide to form rutile titanium dioxide on the ruthenium(IV) oxide by atomic layer deposition. Some methods include exposing transition metal to an atmosphere consisting essentially of O2, NO, and N2O.

Abstract: Methods for forming ruthenium films and semiconductor devices, such as capacitors, that include the films are provided.

Abstract: A method for using a metal bilayer is disclosed. First, a bottom electrode is provided. Second, a dielectric layer which is disposed on and is in direct contact with the lower electrode is provided. Then, a metal bilayer which serves as a top electrode in a capacitor is provided. The metal bilayer is disposed on and is in direct contact with the dielectric layer. The metal bilayer consists of a noble metal in direct contact with the dielectric layer and a metal nitride in direct contact with the noble metal.

Abstract: A method for using a metal bilayer is disclosed. First, a bottom electrode is provided. Second, a dielectric layer which is disposed on and is in direct contact with the lower electrode is provided. Then, a metal bilayer which serves as a top electrode in a capacitor is provided. The metal bilayer is disposed on and is in direct contact with the dielectric layer. The metal bilayer consists of a noble metal in direct contact with the dielectric layer and a metal nitride in direct contact with the noble metal.

Abstract: Methods of forming a capacitor including forming a titanium nitride material within at least one aperture defined by a support material, forming a ruthenium material within the at least one aperture over the titanium nitride material, and forming a first conductive material over the ruthenium material within the at least one aperture. The titanium nitride material may be oxidized to a titanium dioxide material. A second conductive material may be formed over a surface of the titanium dioxide material. A semiconductor device may include at least one capacitor, wherein a major longitudinal portion of the at least one capacitor is not surrounded by a solid material. The capacitor may include a first electrode; a ruthenium oxide material laterally adjacent the first electrode; a rutile titanium dioxide material laterally adjacent the ruthenium oxide material; and a second electrode laterally adjacent the rutile titanium dioxide material.

Abstract: Methods of forming a capacitor including forming at least one aperture in a support material, forming a titanium nitride material within the at least one aperture, forming a ruthenium material within the at least one aperture over the titanium nitride material, and forming a first conductive material over the ruthenium material within the at least one aperture. The support material may then be removed and the titanium nitride material may be oxidized to form a titanium dioxide material. A second conductive material may then be formed over an outer surface of the titanium dioxide material.

Abstract: Methods of forming rutile titanium dioxide comprise exposing a transition metal (such as V, Cr, W, Mn, Ru, Os, Rh, Ir, Pt, Ge, Sn, or Pb) to an atmosphere consisting of oxygen gas (O2) to produce an oxidized transition metal over an unoxidized portion of the transition metal. Rutile titanium dioxide is formed over the oxidized transition metal by atomic layer deposition. The oxidized transition metal is sequentially exposed to a titanium halide precursor and an oxidizer. Other methods include oxidizing a portion of a ruthenium material to ruthenium(IV) oxide using an atmosphere consisting of O2, nitric oxide (NO), or nitrous oxide (N2O); and introducing a gaseous titanium halide precursor and water vapor to the ruthenium(IV) oxide to form rutile titanium dioxide on the ruthenium(IV) oxide by atomic layer deposition. Some methods include exposing transition metal to an atmosphere consisting essentially of O2, NO, and N2O.

Abstract: A method for forming a stacking structure, including forming a ruthenium oxide layer over a substrate; forming a praseodymium oxide layer over the ruthenium oxide layer; and forming a titanium oxide layer over the praseodymium oxide layer; wherein the titanium oxide layer has a rutile phase with the existence of the praseodymium oxide layer underneath. The oxide layers are deposited by a plurality of atomic layer deposition cycles using ruthenium precursor, praseodymium precursor, titanium precursor, and ozone.

Abstract: Methods of forming rutile titanium dioxide. The method comprises exposing a transition metal (such as V, Cr, W, Mn, Ru, Os, Rh, Ir, Pt, Ge, Sn, or Pb) to oxygen gas (O2) to oxidize the transition metal. Rutile titanium dioxide is formed over the oxidized transition metal. The rutile titanium dioxide is formed by atomic layer deposition by introducing a gaseous titanium halide precursor and water to the oxidized transition metal. Methods of forming semiconductor structures having rutile titanium dioxide are also disclosed.