Abstract: A method of forming (and apparatus for forming) refractory metal nitride layers (including silicon nitride layers), such as a tantalum (silicon) nitride barrier layer, on a substrate by using a vapor deposition process with a refractory metal precursor compound, a disilazane, and an optional silicon precursor compound.

Abstract: A method of forming (and an apparatus for forming) a metal oxide layer on a substrate, particularly a semiconductor substrate or substrate assembly, using a vapor deposition process and one or more precursor compounds that include diketonate ligands and/or ketoimine ligands.

Abstract: A method of forming (and apparatus for forming) tantalum suicide layers (including tantalum silicon nitride layers), which are typically useful as diffusion barrier layers, on a substrate by using a vapor deposition process with a tantalum halide precursor compound, a silicon precursor compound, and an optional nitrogen precursor compound.

Abstract: A method of forming (and an apparatus for forming) a metal-doped aluminum oxide layer on a substrate, particularly a semiconductor substrate or substrate assembly, using a vapor deposition process.

Abstract: A method of forming (and apparatus for forming) a tantalum oxide layer on a substrate, particularly a semiconductor substrate or substrate assembly, using a vapor deposition process and a tantalum precursor compound that includes alkoxide ligands, for example.

Abstract: A method of forming (and apparatus for forming) refractory metal nitride layers (including silicon nitride layers), such as a tantalum nitride barrier layer, on a substrate by using an atomic layer deposition process (a vapor deposition process that includes a plurality of deposition cycles) with a refractory metal precursor compound, an organic amine, and an optional silicon precursor compound.

Abstract: A method of forming (and an apparatus for forming) a metal oxide layer on a substrate, particularly a semiconductor substrate or substrate assembly, using a vapor deposition process and one or more precursor compounds that include organo-amine ligands and one or more precursor compounds that include organo-oxide ligands.

Abstract: A method of forming (and apparatus for forming) refractory metal oxide layers, such as tantalum pentoxide layers, on substrates by using vapor deposition processes with refractory metal precursor compounds and ethers.

Abstract: A method of forming (and apparatus for forming) a zirconium and/or hafnium-containing layer on a substrate, particularly a semiconductor substrate or substrate assembly, using a vapor deposition process and one or more silicon precursor compounds of the formula Si(OR)4 with one or more zirconium and/or hafnium precursor compounds of the formula M(NR′R″)4, wherein R, R′, and R″ are each independently an organic group and M is zirconium or hafnium.

Abstract: A method of forming (and apparatus for forming) a layer, such as a strontium titanate, barium titanate, or barium-strontium titanate layer, on a substrate by employing a vapor deposition method, particularly a multi-cycle atomic layer deposition process.

Abstract: A method of forming a film on a substrate using one or more complexes containing one or more chelating O- and/or N-donor ligands. The complexes and methods are particularly suitable for the preparation of semiconductor structures using chemical vapor deposition techniques and systems.

Abstract: An atomic layer deposition method includes positioning a semiconductor substrate within an atomic layer deposition chamber. A first precursor gas is flowed to the substrate within the atomic layer deposition chamber effective to form a first monolayer on the substrate. The first precursor gas flowing comprises a plurality of first precursor gas pulses. The plurality of first precursor gas pulses comprises at least one total period of time between two immediately adjacent first precursor gas pulses when no gas is fed to the chamber. After forming the first monolayer on the substrate, a second precursor gas different in composition from the first is flowed to the substrate within the deposition chamber effective to form a second monolayer on the first monolayer. Other aspects and implementations are contemplated.

Abstract: A supercritical etching composition and method for etching an inorganic material of a semiconductor-based substrate are provided. The method includes providing a semiconductor-based substrate having an exposed inorganic material and exposing the substrate to the supercritical etching composition, whereby exposed inorganic material is removed from the substrate. In one embodiment, the supercritical etching composition includes a supercritical component, which is not capable of etching a particular exposed inorganic material, and a nonsupercritical etching component, which is capable of etching the particular exposed inorganic material. In another embodiment, the supercritical etching composition includes a supercritical component, which is capable of etching the particular exposed inorganic material.

Abstract: Mixed metal aluminum nitride and boride diffusion barriers and electrodes for integrated circuits, particularly for DRAM cell capacitors. Also provided are methods for CVD deposition of MxAlyNzBw alloy diffusion barriers, wherein M is Ti, Zr, Hf, V, Nb, Ta, Cr, Mo, or W; x is greater than zero; y is greater than or equal to zero; the sum of z and w is greater than zero; and wherein when y is zero, z and w are both greater than zero.

Abstract: In one aspect, the invention encompasses a semiconductor processing method of forming a metal-comprising layer over a substrate. A substrate is provided within a reaction chamber, and a source of a metal-comprising precursor is provided external to the reaction chamber. The metal-comprising precursor comprises a metal coordinated with at least one Lewis base to form a complex having a stoichiometric ratio of the at least one Lewis base to the metal. An amount of the at least one Lewis base is distributed within the source to an amount that is in excess of the stoichiometric ratio. At least some of the metal-comprising precursor is transported from the source to the reaction chamber. A metal is deposited from the metal-comprising precursor and onto the substrate within the reaction chamber. In another aspect, the invention encompasses a method of storing a metal-comprising material. A metal-comprising material is dispersed within a solution.

Abstract: The present invention provides methods for the preparation of compounds of the formula (Formula I):

Abstract: The invention includes atomic layer deposition methods and chemical vapor deposition methods. In a particular aspect of the invention, a source of microwave radiation is provided proximate a reaction chamber. At least a fragment of a precursor material is chemisorbed on a substrate within the reaction chamber while not exposing the precursor material to microwave radiation from the source. Excess precursor material is removed from the chamber, and the chemisorbed material is subsequently exposed to microwave radiation from the source within the reaction chamber.

Abstract: A method of forming a phosphorus- and/or boron-containing silica layer, such as a PSG, BSG, or BPSG layer, on a substrate, such as a semiconductor substrate or substrate assembly.

Abstract: Multi-metallic films are prepared from multi-metallic mixtures of metalloamide compounds. The mixtures are subjected to vaporization to form a multi-metallic vapor having defined and controllable stoichiometry. The multi-metallic vapor is then transferred to a chemical vapor deposition chamber, with or without the presence of a reactant gas, to form the multi-metallic film. Multi-metallic nitride, oxide, sulfide, boride, silicide, germanide, phosphide, arsenide, selenide, telluride, etc. films may be prepared by appropriate choice of metalloamide compounds and reactant gas(es).

Abstract: An aluminum-containing material deposition method includes depositing a first precursor on a substrate in the substantial absence of a second precursor. The first precursor can contain a chelate of Al(NR1R2)x(NR3(CH2)zNR4R5)y or Al(NR1R2)x(NR3(CH2)zOR4)y; where x is 0, 1, or 2; y is 3−x; z is an integer 2 to 8; and R1 to R5 are independently selected from among hydrocarbyl groups containing 1 to 10 carbon atoms with silicon optionally substituted for one or more carbon atoms. The method includes depositing the second precursor on the first deposited precursor, the second precursor containing a nitrogen source or an oxidant. A deposition product of the first and second precursors includes at least one of an aluminum nitride or an aluminum oxide. The deposition method can be atomic layer deposition where the first and second precursors are chemisorbed or reacted as monolayers. The first precursor can further be non-pyrophoric.