Abstract: A precursor liquid comprising several metal 2-ethylhexanoates, such as strontium, tantalum and bismuth 2-ethylhexanoates, in a solvent such as xylenes/methyl ethyl ketone and a small amount of hexamethyl-disilazane. The liquid is dried, baked, and annealed to form a thin film of a layered superlattice material, such as strontium bismuth tantalate, on the substrate.

Abstract: A precursor liquid comprising several metal 2-ethylhexanoates, such as strontium, tantalum and bismuth 2-ethylhexanoates, in a xylenes/methyl ethyl ketone solvent is prepared, a substrate is placed within a vacuum deposition chamber, a small amount of hexamethyl-disilazane is added to the precursor liquid is misted, and the mist is flowed into the deposition chamber while maintaining the chamber at ambient temperature to deposit a layer of the precursor liquid on the substrate. The liquid is dried, baked, and annealed to form a thin film of a layered superlattice material, such as strontium bismuth tantalate, on the substrate. Then an integrated circuit is completed to include at least a portion of the layered superlattice material film in a component of the integrated circuit.

Abstract: A precursor liquid comprising several metal 2-ethylhexanoates, such as strontium, tantalum and bismuth 2-ethylhexanoates, in a xylenes/methyl ethyl ketone solvent is prepared, a substrate is placed within a vacuum deposition chamber, a small amount of hexamethyl-disilazane is added to the precursor liquid is misted, and the mist is flowed into the deposition chamber while maintaining the chamber at ambient temperature to deposit a layer of the precursor liquid on the substrate. The liquid is dried, baked, and annealed to form a thin film of a layered superlattice material, such as strontium bismuth tantalate, on the substrate. Then an integrated circuit is completed to include at least a portion of the layered superlattice material film in a component of the integrated circuit.

Abstract: Metal alkoxycarboxylate-based liquid precursor solutions are used to form electronic devices (100) that include mixed layered superlattice materials of a type having discrete oxygen octahedral layers and collated with a superlattice-generator layer. The precursor solutions include a plurality of metal moieties in effective amounts for yielding the layered superlattice materials. These metal moieties are mixed to include an A/B portion capable of forming an A/B layer, a perovskite-like AB layer portion capable of forming a perovskite-like AB octahedral layer, and a superlattice-generator portion capable of forming the superlattice-generator layer. The precursors are deposited in liquid form upon a substrate and annealed to provide the layered superlattice materials.

Abstract: A liquid precursor containing a metal is applied to a substrate, RTP baked, and annealed to form a layered superlattice material. Prebaking the substrate and oxygen in the RTP and anneal is essential, except for high bismuth content precursors. Excess bismuth between 110% and 140% of stoichiometry and RTP temperature of 725.degree. C. is optimum. The film is formed in two layers, the first of which uses a stoichiometric precursor and the second of which uses an excess bismuth precursor. The electronic properties are so regularly dependent on process parameters and material composition, and such a wide variety of materials are possible, that electronic devices can be designed by selecting from a continuous record of the values of one or more electronic properties as a continuous function of the process parameters and material composition, and utilizing the selected process and material composition to make a device.

Abstract: An integrated circuit memory, MMIC, or other device including a dielectric comprising lead-tin zirconium-titanium oxide (PSZT). The proportion of tin ranges from 30% to 50% of the total amount of tin, zirconium and titanium. The dielectric is formed by applying a first liquid precursor having 10% excess lead to a substrate and heating it to form a first PSZT thin film, applying a second liquid precursor having 5% excess lead to the first thin film and heating to form a second thin film, then applying the first liquid precursor and heating to form a third thin film, and annealing the three thin films together to form a PSZT dielectric layer.

Abstract: Metal alkoxycarboxylate-based liquid precursor solutions are used to form electronic devices (100) that include mixed layered superlattice materials (112) of a type having discrete oxygen octahedral layers (124) and (128) collated with a superlattice-generator layer (116). The precursor solutions include a plurality of metal moieties in effective amounts for yielding the layered superlattice materials. These metal moieties are mixed to include an A/B portion capable of forming an A/B layer (124), a perovskite-like AB layer portion capable of forming a perovskite-like AB octahedral layer (128), and a superlattice-generator portion capable of forming the superlattice-generator layer (116). The precursors are deposited in liquid form upon a substrate and annealed to provide the layered superlattice materials.

Abstract: A photosensitive liquid solution is used to make thin films for use in integrated circuits. The photosensitive liquid solution contains a photo initiator, and solvent, and a mixture of metals bonded to free-radical-susceptible monomers. The metals are mixed in amounts corresponding to the desired stoichiometry of a metal oxide thin film that derives from the. The photosensitive liquid solution is applied to a substrate, soft baked, and exposed to ultraviolet radiation under a photo mask. The ultraviolet radiation patterns the soft-baked film through a free radical polymerization chain reaction. A solvent etch is used to remove the unpolymerized portion of the polymerized film. The remaining thin film pattern is annealed to provide a patterned metal oxide film.

Abstract: A metal organic liquid precursor solution includes metal organic complexes dispersed in an ester solvent. The ester solvent has medium length carbon chains to prevent the precipitation of strongly electropositive metals in solution. A liquid precursor solution is used to make thin film metal oxides of uniform thickness and consistent quality.

Abstract: Thin film ferroelectric materials for use in integrated memory circuits, such as FERAMS and the like, contain strontium bismuth niobium tantalate having an empirical formula SrBi.sub.2+E (Nb.sub.X Ta.sub.2-X)O.sub.9+3E/2, wherein E is a number representing an excess amount of bismuth ranging from zero to 2; and X is a number representing an excess amount of niobium ranging from 0.01 to 0.9. The thin films demonstrate an exceptional resistance to polarization imprinting when challenged with unidirectional voltage pulses.

Abstract: A precursor liquid comprising silicon in a xylenes solvent is prepared, a substrate is placed within a vacuum deposition chamber, the precursor liquid is misted, and the mist is flowed into the deposition chamber while maintaining the chamber at ambient temperature to deposit a layer of the precursor liquid on the substrate. The liquid is dried, baked, and annealed to form a thin film of silicon dioxide or silicon glass on the substrate. Then an integrated circuit is completed to include at least a portion of the silicon dioxide or silicon glass layer as an insulator for an electronic device in the integrated circuit.

Abstract: An electrode for a ferroelectric electronic device is formed on an SiO.sub.2 isolation layer by depositing an adhesion layer, such as titanium, between about 25 .ANG. and 500 .ANG. thick, then a layer of a nobel metal, such as platinum, that is at least 10 times thicker than the adhesion layer. The electrode is then annealed at a temperature higher than the minimum oxide eutectic temperature of the adhesion layer. The electrode is moved into the annealing furnace at a ramp rate such that it reaches its anneal temperature in five minutes or less. The relative thinness of the adhesion layer and the quick ramp up of the anneal causes all the titanium to be tied up in the oxide before it can diffuse through the platinum, and prevents the formation of rutile phases of the titanium and defects such as voids and hillocks in the platinum, which can destabilize the electrode.

Abstract: A method of fabricating a ferroelectric or layered superlattice DRAM compatible with conventional silicon CMOS technology. A MOSFET is formed on a silicon substrate. A thick layer of BPSG followed by a thin SOG layer overlies the MOSFET. A capacitor is formed by depositing a layer of platinum, annealing, depositing an intermediate layer comprising a ferroelectric or layer superlattice material, annealing, depositing a second layer of platinum, then patterning the capacitor. Another SOG layer is deposited, contact holes to the MOSFET and capacitor are partially opened, the SOG is annealed, the contact holes are completely opened, and a Pt/Ti/PtSi wiring layer is deposited.

Abstract: A thin-film zinc oxide varistor (10) for use in integrated circuits and the like is produced by applying a polyoxyalkylated metal complex, such as a metal alkoxycarboxylate, to a substrate (12, 14, and 16) for the formation of a dried nonohmic layer (18). The method of production includes the steps of providing a substrate and a precursor solution including a polyoxyalkylated zinc complex (P22, P24), coating a portion of the substrate with the precursor solution (P26), drying the coated substrate (P32), and crystallizing the dried thin-film zinc oxide layer (P30). The resultant crystalline zinc oxide varistor layer (18) may be doped with bismuth, yttrium, praseodymium, cobalt, antimony, manganese, silicon, chromium, titanium, potassium, dysprosium, cesium, cerium, and iron to provide a non-ohmic varistor. The varistor layer (10) is annealed at a temperature ranging from about 400 to about 1000.degree. C.

Abstract: A precursor liquid comprising several metal 2-ethylhexanoates, such as stroritium tantalum and bismuth 2-ethylhexanoates, in a xylenes/methyl ethyl ketone solvent is prepared, a substrate is placed within a vacuum deposition chamber, the precursor liquid is misted, and the mist is flowed into the deposition chamber while maintaining the chamber at ambient temperature to deposit a layer of the precursor liquid on the substrate. The liquid is dried, baked, and annealed to form a thin film of a layered superlattice material, such as strontium bismuth tantalate, on the substrate. Then an integrated circuit is completed to include at least a potion of the layered superlattice material film in a component of the integrated circuit.

Abstract: A first metal, an alcohol, and a carboxylic acid are reacted to form a metal alkoxycarboxylate which is then reacted with an alkoxide and/or a carboxylate of a second metal to form a precursor. Alternatively, a metal carboxylate and a metal alkoxide are combined and heated to form a precursor. In either alternative, the precursor includes all or most of the metal-oxygen-metal bonds of a desired metal oxide and a carboxylate ligand. The precursor is applied to a substrate, dried and annealed to form the metal oxide, such as BST. The metal-oxygen-metal bonds in the precursor permit the desired metal oxide to be formed from the precursor in one step, providing excellent thin films suitable for integrated circuits. The carboxylate ligand provides stability to the precursor allowing it to be stored for periods common in large scale manufacturing.

Abstract: A precursor liquid comprising barium and strontium 2-ethylhexanoates and titanium 2-methoxyethanol in a 2-methoxyethanol solvent is prepared, a substrate is placed within a vacuum deposition chamber, the precursor liquid is misted, and the mist is flowed into the deposition chamber while maintaining the chamber at ambient temperature to deposit a layer of the precursor liquid on the substrate. The liquid is dried, baked, and annealed to form a thin film of barium strontium titanate on the substrate. Then an integrated circuit is completed to include at least a portion of the layered superlattice material film in a component of the integrated circuit.

Abstract: Metals are reacted in a first solvent, such as 2-methoxyethanol, to form an initial precursor comprising metal-oxide compounds dissolved in the first solvent. A second solvent, such as xylene, that does not react with the metal is added to the solution and the solution heated to distill away the first solvent and form a final precursor. The final precursor is spin-coated on an integrated circuit substrate then dried and annealed to form a thin film of a metal oxide. For metal oxides including bismuth, the bismuth precursor is added to a cold initial precursor and the final precursor is not heated after the bismuth precursor is added. The second solvent wets the substrate better than the first solvent and has a better viscosity for spin-coating, thus resulting in a denser thin film with fewer imperfections.

Abstract: An oversize ferroelectric capacitor is located against the contact hole to the MOSFET source/drain in a DRAM. A barrier layer made of titanium nitride, titanium tungsten, tantalum, titanium, tungsten, molybdenum, chromium, indium tin oxide, tin dioxide, ruthenium oxide, silicon, silicide, or polycide lies between the ferroelectric layer and the source drain. The barrier layer may act as the bottom electrode of the ferroelectric capacitor, or a separate bottom electrode made of platinum may be used. In another embodiment in which the barrier layer forms the bottom electrode, an oxide layer less than 5 nm thick is located between the barrier layer and the ferroelectric layer and the barrier layer is made of silicon, silicide, or polycide. A thin silicide layer forms and ohmic contact between the barrier layer and the source/drain. The capacitor and the barrier layer are patterned in a single mask step. The ends of the capacitor are stepped or tapered.

Abstract: A precursor is made by mixing a metal alkoxycarboxylate-containing liquid with a 2-ethylhexanoic acid in an effective amount for shelf-stabilizing said liquid by substituting 2-ethylhexanoate ligands for alkoxide ligands, thereby forming a mixture, and heating said mixture to substitute said carboxylate ligands for said alkoxide ligands. Specficially, a barium strontium titanate precursor and a strontium bismuth tantalate precursor are made by combining polyoxyalkylated metal moieties to form a liquid solution in which the metal atoms bond with an oxygen atom in a ligand selected from a ligand group consisting of alkoxides and carboxylates, then then heating the liquid solution.