A method and apparatus for producing hydrogen and a passivating oxide using water splitting techniques is disclosed. The apparatus comprises a container filled with a passivating-oxide preventing agent that is substantially inert to water in an effective amount to prevent passivation of a solid-state material during oxidation and a conduit for inserting a solid-state material into the passivating-oxide preventing agent in which the solid-state material is submerged in the passivating-oxide preventing agent without being in direct contact with water. The solid-state material is capable of dissolving in the passivating-oxide preventing agent and reacting with the water. Thus, the method provides continuous dissolution of the solid-state material into the passivating-oxide preventing agent and its alloys in the presence of excess water at or near room temperature to enable continuous generation of hydrogen, passivating oxide and heat.

A method and apparatus for producing hydrogen and a passivating oxide using water splitting techniques is disclosed. The apparatus comprises a container filled with a passivating-oxide preventing agent that is substantially inert to water in an effective amount to prevent passivation of a solid-state material during oxidation and a conduit for inserting a solid-state material into the passivating-oxide preventing agent in which the solid-state material is submerged in the passivating-oxide preventing agent without being in direct contact with water. The solid-state material is capable of dissolving in the passivating-oxide preventing agent and reacting with the water. Thus, the method provides continuous dissolution of the solid-state material into the passivating-oxide preventing agent and its alloys in the presence of excess water at or near room temperature to enable continuous generation of hydrogen, passivating oxide and heat.

Disclosed herein is a method for reducing a metal oxide in a metal oxide containing precursor. The method comprises providing a reaction mixture comprising the metal oxide containing precursor and an aluminium reductant; heating the reaction mixture in the presence of solid or gaseous aluminium chloride to a temperature at which reactions that result in the metal oxide being reduced are initiated; controlling reaction conditions whereby the reaction mixture is prevented from reaching a temperature at which thermal runaway can occur; and isolating reaction products that include reduced metal oxide.

Disclosed herein is a method for reducing a metal oxide in a metal oxide containing precursor. The method comprises providing a reaction mixture comprising the metal oxide containing precursor and an aluminium reductant; heating the reaction mixture in the presence of solid or gaseous aluminium chloride to a temperature at which reactions that result in the metal oxide being reduced are initiated; controlling reaction conditions whereby the reaction mixture is prevented from reaching a temperature at which thermal runaway can occur; and isolating reaction products that include reduced metal oxide.

The present invention relates to a waste battery treatment method which includes preparing a waste battery including a waste positive electrode which includes an aluminum current collector and a positive electrode active material layer formed on at least one surface of the aluminum current collector, heat treating the waste battery at a temperature of 650 C. or higher in an air atmosphere or oxidizing atmosphere to convert the aluminum current collector into aluminum oxide, and recovering aluminum oxide powder and positive electrode active material powder from the heat-treated waste battery.