Abstract: A lithium niobate with high lithium ion conductivity. Disclosed is a method for producing a lithium niobate for use in a covering layer covering at least part of a surface of cathode active material particles, the method comprising: preparing a solution containing niobium ions and lithium ions, drying the solution to obtain a lithium niobate precursor, and heating the lithium niobate precursor at a temperature of from 250° C. to 300° C. for a heating time of more than 0 minute and 10 minutes or less.

Abstract: A process for the production of energetically rich compounds comprising: using externally supplied thermal energy to heat an electrolyzable compound to a temperature greater than the ambient temperature; generating electricity from a solar electrical photovoltaic component; subjecting the heated electrolyzable compound to electrolysis with the solar generated electricity to generate an energetically rich electrolytic product.

Abstract: A method of producing iron by: solubilizing iron oxide as a lithiated iron oxide in a molten carbonate having lithium carbonate; and subjecting the lithiated iron oxide to electrolysis to obtain iron and oxygen. The molten alkali metal carbonate salt may further include lithium oxide. Additionally the lithium carbonate may be simultaneously subjected to electrolysis to produce steel instead of iron.

Abstract: The present invention relates to an electrolytic process, methods and apparatus for the preparation of carbon monoxide and in particular to electrolysis of molten carbonates to yield carbon monoxide which may be used for chemical storage of electrical energy and further as chemical feedstock for other organic products.

Abstract: The present invention relates to processes for making calcium oxide electrolytically using calcium carbonate as a starting material. In a direct process, the present invention involves heating calcium carbonate to a temperature greater than its melting point or heating a molten mixture containing calcium carbonate; and subjecting the molten calcium carbonate or molten mixture to electrolysis to generate calcium oxide and oxygen, and a reduced carbon product.

Abstract: The present invention relates to an electrolytic process, methods and apparatus for the preparation of carbon monoxide and in particular to electrolysis of molten carbonates to yield carbon monoxide which may be used for chemical storage of electrical energy and further as chemical feedstock for other organic products.

Abstract: The present invention pertains to a method for removing a substance (X) from a solid metal or semi-metal compound (M1X) by electrolysis in a melt of M2Y, which comprises conducting the electrolysis under conditions such that reaction of X rather than M2 deposition occurs at a electrode surface, and that X dissolves in the electrolyte M2Y. The substance X is either removed from the surface (i.e., M1X) or by means of diffusion extracted from the case material. The temperature of the fused salt is chosen below the melting temperature of the metal M1. The potential is chosen below the decomposition potential of the electrolyte.

Abstract: A method for the electrochemical synthesis of dinitro compounds is disclosed. The method comprises using an anode to oxidize an inactive chemical mediator, such as a ferrocyanide (Fe(CN)6?4) ion, to an active chemical mediator or oxidizing agent, such as a ferricyanide (Fe(CN)6?3) ion, in the presence of a differential voltage. The oxidizing agent reacts with a nitro compound and a nitrite ion to form a geminal dinitro compound. The anode may continuously oxidize ferrocyanide to regenerate active ferricyanide, thus keeping sufficient amounts of ferricyanide available for reaction.

Abstract: An electrolytic apparatus for an oxide electrolytic method includes an interior of an electrolytic vessel, a common cathode and two types of anodes different in shape and arrangement, a first electrolysis controller is connected between the cathode and the first anode, and a second electrolysis controller is connected between the cathode and the second anode. The electrolytic processing of the substance in the electrolytic vessel is carried out such that a pair of the cathode and one of the anodes is used for main electrolysis and a pair of the cathode and the other anode is used for auxiliary electrolysis. By this apparatus, prevention of the ununiform distribution of the electrodeposit, improvement of the processing speed and improvement of the durability of the crucible are achieved, whereby the recycling of spent nuclear fuels based on the nonaqueous reprocessing method is made feasible in a commercial scale.

Abstract: Aluminum electrolysis cells and associated system and methods are disclosed. In one embodiment, an aluminum electrolysis cell includes an outer shell, a bottom, a plurality of bath resistant blocks defining a surrounding wall, and at least one spring member coupled to at least one of the plurality of bath resistant blocks and the outer shell, where the at least one spring member is configured to maintain the plurality of bath resistant blocks in a substantially leak-tight configuration.

Abstract: The aim of the present invention is a process for preparing a mineral matrix by melting, which is implemented according to the method of direct cold crucible induction melting. The method employs a step for initiating the melting. During the initiation step, a conductive mineral load is generated, by introduction of constituent elements of the matrix, into a bath of a conductive liquid, brought by induction to a suitable temperature, in the cold crucible. The intervening conductive liquid has the property of being a liquid and an electric conductor at a temperature between &thgr;1 of less than 600° C., advantageously of between 100 and 500° C., and a temperature &thgr;2 at least equal to the temperature at which the constituent elements of the matrix melt to generate the matrix. The conductive liquid is advantageously a molten sodium hydroxide bath. The preparation of such a glass matrix is advantageously implemented within the context of a method of vitrifying radioactive waste materials.

Abstract: An integrated system for producing high purity silicon dioxide comprising: a) a source of an oxygen-containing feed gas containing at least one impurity, b) an oxygen transport membrane cell containing an oxygen-selective transport membrane that has a cathode side and an opposing anode side, the membrane being at an elevated temperature effective for separation of oxygen in the feed gas from the impurity by transporting oxygen ions from the oxygen-containing feed gas through the membrane to the anode to form a purified oxygen permeate on the anodeside, while retaining an essentially oxygen-depleted, impurity-containing retentate on the cathode side, c) a passageway from the source (a) to the cathode side of the membrane cell, d) a silicon source, and e) a silicon oxidation furnace, in communication with the anode side of the membrane cell, for reaction of the purified oxygen permeate with silicon from the silicon source, at an elevated reaction temperature effective for the reaction, in order to produce the h

Abstract: A cermet composite material is made by treating at an elevated temperature a mixture comprising a compound of iron and a compound of at least one other metal, together with an alloy or mixture of copper and a noble metal. The alloy or mixture preferably comprises particles having an interior portion containing more copper than noble metal and an exterior portion containing more noble metal than copper. The noble metal is preferably silver. The cermet composite material preferably includes alloy phase portions and a ceramic phase portion. At least part of the ceramic phase portion preferably has a spinel structure.

Abstract: Crystalline REBa.sub.2 Cu.sub.3 O.sub.7-x superconductors are obtained by a constant-potential or current density electrochemical deposition in an alkaline hydroxide molten flux in a three-electrode, single-compartment cell operating at a temperature below 500.degree. C.