An adsorbent for phosphoric acid-based anionic substances, that contains foamed glass, and that has a Ca2p concentration of 7.5 atom % or more or a Na1s concentration of 5.0 atom % or less at the surface thereof as measured by XPS analysis, and a half-width of Si2p peak of 2.4 eV or more. The adsorbent can also have a specific surface area of 45 m.sup.2/g or more or a pore volume of 2.5 cm.sup.3/g or more as measured by mercury intrusion.

The invention relates to a method and system for phosphate recovering from a waste stream, such as an animal manure waste stream. The method comprises the steps of: - providing a tank reactor, 5 - providing acidogenic bacteria and/or acetogenic bacteria and the waste stream to the tank reactor, - hydrolysing the waste stream, forming a reaction mixture; - providing a gas flow to the reaction mixture for removing carbon dioxide from the reaction mixture; 10 - providing the reaction mixture to an anaerobic sludge reactor, - removing a compound comprising phosphate from the reaction mixture within the anaerobic sludge reactor, and - removing gas from the reaction mixture within the anaerobic sludge reactor.

The present invention provides a process for the preparation of phosphor aerogel of uniform size having high porosity, low density; high thermal insulation and high luminescence, which is useful for various applications like lighting, display, sensing and other applications.

More specifically, the present invention provides a simple and versatile process for the formation of monolithic gel, at room temperature, which on further drying at supercritical temperature and pressure result in dry aerogel. Further, annealing under mild reduced atmosphere from 1000°-1400° C. not only retains the porous network with uniform size particles but also crystallizes to form a phosphor aerogel having brightest luminescence with bulk density as low as 100 kg m-3, and strong enough to support a weight much higher than its own weight.

This disclosure describes methods, processes and devices that remove or release organics from ores, such as phosphate ores or secondary sources such as mine tailings or waste. The method comprises: preparing an ore to a pre-set size; mixing the ore with an acidic reagent having an initial pH value in a slurry comprising the ore and the reagent; and while mixing the slurry, maintaining a pH level in the slurry to a pH range. While mixing the slurry, the slurry may produce a supernatant containing organic material removed from the ore and sediment containing refined ore. The method may also screen the slurry to create a first stream of materials that does not pass through the screen and a second stream of materials and refined ore that pass through the screen.

The invention provides a method for preparing lithium manganese iron phosphate, which includes the following steps: S1: mixing a manganese source and/or an iron source in solid phase to obtain a first mixture; S2: sintering the first mixture in solid phase at 300° C. to 1200° C. to obtain a manganese iron oxide (MnxFe1−x−y)mOn; S3: mixing the manganese iron oxide (MnxFe1−x−y)mOn with a lithium source, a phosphorus source, and optionally a manganese source and/or an iron source in solid phase to obtain a second mixture; and S4: sintering the second mixture in solid phase at 350° C. to 900° C. to obtain lithium manganese iron phosphate LiMnxFe1−x−yPO4, wherein 0≤x≤1, and 0≤y≤1. The method of the present invention can be used to prepare a lithium manganese iron phosphate material with high tap density, long cycle life, low costs, and high cost-effectiveness.

Methods of making a lithium mixed metal compound by reaction of starting materials are provided. The methods can include reacting and/or processed reacted starting materials to form the lithium mixed metal compound in the presence of a fluorine rich atmosphere or media.

Described are a solid material which has ionic conductivity for lithium ions, a process for preparing said solid material, a use of said solid material as a solid electrolyte for an electrochemical cell, a solid structure selected from the group consisting of a cathode, an anode and a separator for an electrochemical cell, and an electrochemical cell comprising such solid structure.

This disclosure describes methods, processes and devices that remove or release organics from ores, such as phosphate ores or secondary sources such as mine tailings or waste. The method comprises: preparing an ore to a pre-set size; mixing the ore with a reagent having an initial pH value in a slurry comprising the ore and the reagent; and while mixing the slurry, maintaining a pH level in the slurry to a pH range. While mixing the slurry, the slurry may produce a supernatant containing organic material removed from the ore and sediment containing refined ore. The method may also screen the slurry to create a first stream of materials that does not pass through the screen and a second stream of materials and refined ore that pass through the screen.

An adsorbent for phosphoric acid-based anionic substances, that contains foamed glass, and that has a Ca2p concentration of 7.5 atom % or more or a Na1s concentration of 5.0 atom % or less at the surface thereof as measured by XPS analysis, and a half-width of Si2p peak of 2.4 eV or more. The adsorbent can also have a specific surface area of 45 m.sup.2/g or more or a pore volume of 2.5 cm.sup.3/g or more as measured by mercury intrusion.

The present invention provides a process for the preparation of phosphor aerogel of uniform size having high porosity, low density; high thermal insulation and high luminescence, which is useful for various applications like lighting, display, sensing and other applications. More specifically, the present invention provides a simple and versatile process for the formation of monolithic gel, at room temperature, which on further drying at supercritical temperature and pressure result in dry aerogel.