Abstract: An impurity diffusion layer serving as the source or the drain of a transistor is formed in a semiconductor substrate, and a protection insulating film is formed so as to cover the transistor. A capacitor lower electrode, a capacitor dielectric film of an oxide dielectric film and a capacitor upper electrode are successively formed on the protection insulating film. A plug for electrically connecting the impurity diffusion layer of the transistor to the capacitor lower electrode is buried in the protection insulating film. An oxygen barrier layer is formed between the plug and the capacitor lower electrode. The oxygen barrier layer is made from a composite nitride that is a mixture or an alloy of a first nitride having a conducting property and a second nitride having an insulating property.

Abstract: After forming a lower electrode by patterning a conducting film formed on a substrate by using an etching gas including chlorine, chlorine remaining on the lower electrode is removed by irradiating the lower electrode with plasma of a gas including fluorine. Thereafter, a capacitor dielectric film made of an insulating metal oxide is formed on the lower electrode, and an upper electrode is formed on the capacitor dielectric film.

Abstract: An impurity diffusion layer serving as the source or the drain of a transistor is formed in a semiconductor substrate, and a protection insulating film is formed so as to cover the transistor. A capacitor lower electrode, a capacitor dielectric film of an oxide dielectric film and a capacitor upper electrode are successively formed on the protection insulating film. A plug for electrically connecting the impurity diffusion layer of the transistor to the capacitor lower electrode is buried in the protection insulating film. An oxygen barrier layer is formed between the plug and the capacitor lower electrode. The oxygen barrier layer is made from a composite nitride that is a mixture or an alloy of a first nitride having a conducting property and a second nitride having an insulating property.

Abstract: A ferroelectric device includes a ferroelectric layer and an electrode. The ferroelectric material is made of a perovskite or a layered superlattice material. A superlattice generator metal oxide is deposited as a capping layer between said ferroelectric layer and said electrode to improve the residual polarization capacity of the ferroelectric layer.

Abstract: A ferroelectric thin film capacitor has smooth electrodes permitting comparatively stronger polarization, less fatigue, and less imprint, as the ferroelectric capacitor ages. The smooth electrode surfaces are produced by DC reactive sputtering.

Abstract: A high dielectric constant insulator including a thin film of a metal oxide selected from the group consisting of tungsten-bronze-type oxides, pyrochlore-type oxides, and combinations of Bi2O3 with an oxide selected from the group consisting of perovskites and pyrochlore-type oxides. An embodiment contains metal oxides represented by the general stoichiometric formulas AB2O6, A2B2O7 and A2Bi2B2O10, wherein A represents A-site atoms selected from the group of metals consisting of Ba, Bi, Sr, Pb, Ca, K, Na and La; and B represents B-site atoms selected from the group of metals consisting of Ti, Zr, Ta, Hf, Mo, W and Nb. Preferably, the metal oxides are (BaxSr1−x)(TayNb1−y)2O6, where 0≦x≦1.0 and 0≦y≦1.0; (BaxSr1−x)2(TayNb1−y)2O7, where 0≦x≦1.0 and 0≦y≦1.0; and (BaxSr1−x)2Bi2(TayNby−1)2O10, where 0≦x≦1.0 and 0≦y≦1.0. Thin films according to the invention have a relative dielectric constant ≧40, and preferably about 100.

Abstract: A high dielectric constant insulator including a thin film of a metal oxide selected from the group consisting of tungsten-bronze-type oxides, pyrochlore-type oxides, and combinations of Bi2O3 with an oxide selected from the group consisting of perovskites and pyrochlore-type oxides. An embodiment contains metal oxides represented by the general stoichiometric formulas AB2O6, A2B2O7 and A2Bi2B2O10, wherein A represents A-site atoms selected from the group of metals consisting of Ba, Bi, Sr, Pb, Ca, K, Na and La; and B represents B-site atoms selected from the group of metals consisting of Ti, Zr, Ta, Hf, Mo, W and Nb. Preferably, the metal oxides are (BaxSr1−x)(TayNb1−y)2O6, where 0≦y≦1.0 and 0≦y≦1.0; (BaxSr1−x)2(TayNB1−y)2O7, where 0≦x≦1.0 and 0≦y≦1.0; and (BaxSr1−x)2(TayNb1−y)2O10, where 0≦x≦1.0 and 0≦y≦1.0. Thin films according to the invention have a relative dielectric constant ≳40, and preferably about 100.

Abstract: A ferroelectric device includes a ferroelectric layer and an electrode. The ferroelectric material is made of a perovskite or a layered superlattice material. A superlattice generator metal oxide is deposited as a capping layer between said ferroelectric layer and said electrode to improve the residual polarization capacity of the ferroelectric layer.

Abstract: A high dielectric constant insulator including a thin film of a metal oxide selected from the group consisting of tungsten-bronze-type oxides, pyrochlore-type oxides, and combinations of Bi2O3 with an oxide selected from the group consisting of perovskites and pyrochlore-type oxides. An embodiment contains metal oxides represented by the general stoichiometric formulas AB2O6, A2B2O7 and A2Bi2B2O10, wherein A represents A-site atoms selected from the group of metals consisting of Ba, Bi, Sr, Pb, Ca, K, Na and La; and B represents B-site atoms selected from the group of metals consisting of Ti, Zr, Ta, Hf, Mo, W and Nb. Preferably, the metal oxides are (BaxSr1−x)(TayNb1−y)2O6, where 0≦x≦1.0 and 0≦y≦1.0; (BaxSr1−x)2(TayNb1−Y)2O7, where 0≦x≦1.0 and 0≦y≦1.0; and (BaxSr1−x)2Bi2(TayNb1−y)2O10, where 0≦x≦1.0 and 0≦y≦1.0. Thin films according to the invention have a relative dielectric constant ≧40, and preferably about 100.

Abstract: A ferroelectric FET having an interface insulator layer containing ZrO2. The ferroelectric FET includes a gate oxide layer, the interface insulator layer is located on the gate oxide layer, and ferroelectric layered superlattice material is located on the interface insulator layer, The interface insulator layer has a thickness of from 15 to 25 nanometers.

Abstract: A thin film of solid material is selectively formed during fabrication of an integrated circuit by applying a liquid precursor to a substrate having a first surface and a second surface and treating the liquid precursor. The first surface has different physical properties than the second surface such that a solid thin film forms on the first surface but does not form on the second surface. The substrate is washed after formation of said solid thin film to remove any residues of said liquid from the second substrate surface.

Abstract: A semiconductor memory includes plural lower electrodes formed on a semiconductor substrate; a capacitor dielectric film of an insulating metal oxide continuously formed over the plural lower electrodes; plural upper electrodes formed on the capacitor dielectric film in positions respectively corresponding to the plural lower electrodes; and plural transistors formed on the semiconductor substrate. The plural lower electrodes are respectively connected with source regions of the plural transistors.

Abstract: A Ti/TiN adhesion/barrier layer is formed on a substrate and annealed. The anneal step is performed at a temperature within a good morphology range of 100° C. above a base barrier anneal temperature that depends on the thickness of said barrier layer. The base barrier anneal temperature is about 700° C. for a barrier thickness of about 1000 Å and about 800° C. for a barrier thickness of about 3000 Å. The barrier layer is 800 Å thick or thicker. A first electrode is formed, followed by a BST dielectric layer and a second electrode. A bottom electrode structure in which a barrier layer of TiN is sandwiched between two layers of platinum is also disclosed. The process and structures also produce good results with other capacitor dielectrics, including ferroelectrics such as strontium bismuth tantalate.

Abstract: A ferroelectric thin film capacitor has smooth electrodes permitting comparatively stronger polarization, less fatigue, and less imprint, as the ferroelectric capacitor ages. The smooth electrode surfaces are produced by carefully controlled drying, soft baking, and annealing conditions.

Abstract: In a method of manufacturing an electronic device, an electronic component and a mount substrate are disposed such that one of surfaces of the electronic component faces toward one of surfaces of the mount substrate, and a connection electrode of the electronic component is electrically connected and mechanically bond to a patterned conductor of the mount substrate. A resin film is then disposed on the electronic component and the mount substrate. A gas captured in between the resin film and the electronic component is sucked through a hole provided in the mount substrate from a side of the mount substrate opposite to the electronic component. The resin film is thereby deformed to closely contact the electronic component and the mount substrate. The resin film is then heated and adhered to the mount substrate.

Abstract: A plurality of liquids, the flow of each controlled by a volumetric flowrate controller, are mixed in a mixer to form a final precursor that is misted and then deposited on a substrate. A physical property of precursor liquid is adjusted by adjusting the volumetric flowrate controllers, so that when precursor is applied to substrate and treated, the resulting thin film of solid material has a smooth and planar surface. Typically the physical property is the viscosity of the precursor, which is selected to be relatively low, in the range of 1-2 centipoise.

Abstract: A plurality of liquids, the flow of each controlled by a volumetric flowrate controller, are mixed in a mixer to form a final precursor that is misted and then deposited on a substrate. A physical property of precursor liquid is adjusted by adjusting the volumetric flowrate controllers, so that when precursor is applied to substrate and treated, the resulting thin film of solid material has a smooth and planar surface. Typically the physical property is the viscosity of the precursor, which is selected to be relatively low, in the range of 1-2 centipoise.

Abstract: An impurity diffusion layer serving as the source or the drain of a transistor is formed in a semiconductor substrate, and a protection insulating film is formed so as to cover the transistor. A capacitor lower electrode, a capacitor dielectric film of an oxide dielectric film and a capacitor upper electrode are successively formed on the protection insulating film. A plug for electrically connecting the impurity diffusion layer of the transistor to the capacitor lower electrode is buried in the protection insulating film. An oxygen barrier layer is formed between the plug and the capacitor lower electrode. The oxygen barrier layer is made from a composite nitride that is a mixture or an alloy of a first nitride having a conducting property and a second nitride having an insulating property.

Abstract: A substrate is located within a deposition chamber, the substrate defining a substrate plane. A liquid precursor is misted by ultrasonic or venturi apparatus, to produce a colloidal mist. The mist is generated, allowed to settle in a buffer chamber, filtered through a system up to 0.01 micron, and flowed into the deposition chamber between the substrate and barrier plate to deposit a liquid layer on the substrate. The liquid is dried to form a thin film of solid material on the substrate, which is then incorporated into an electrical component of an integrated circuit.

Abstract: A liquid precursor containing thallium is applied to a first electrode, RTP baked at a temperature lower than 725° C., and annealed at the same temperature for a time period from one to five hours to yield a ferroelectric layered superlattice material. A second electrode is formed to form a capacitor, and a second anneal is performed at a temperature lower than 725° C. If the material is strontium bismuth thallium tantalate, the precursor contains (m−1) mole-equivalents of strontium for each of (2.2−x) mole-equivalents of bismuth, x mole-equivalents of thallium, and m mole-equivalents of tantalum, where m=2 and 0.0<×≦2.2.