The invention comprises a method comprising heating a solid, naturally occurring mineral so that at least a portion of the solid naturally occurring mineral melts to form an at least partially molten naturally occurring mineral and quenching the at least partially molten naturally occurring mineral in water so that at least a portion of the quenched naturally occurring mineral is in amorphous form.

The present application provides a precise ion implantation type modified geopolymer and an efficient preparation method thereof, wherein the precise ion implantation type modified geopolymer comprise: a geopolymer source material with a specific size, which implanted by Si and Al ions with a designated dose by an ion implanter. The geopolymer source material consists of a mixture of solid waste, alkali activator, and water.

Disclosed herein is a transportable bio-cement comprising a desiccated microorganism package; where the microorganism package comprises one or more microorganisms; a first binder, where the first binder is produced by the microorganism; and where the microorganism has protected itself by a layer of the first binder; where the transportable bio-cement is devoid of moisture. Disclosed herein too is a method of manufacturing a transportable dry composition comprising blending together a microorganism package; a nutrient; and a liquid; activating the microorganism package to produce a first binder; subjecting the microorganism package to desiccation to form a transportable bio-cement; and blending the transportable bio-cement with an aggregate to form a bio-concrete; where the aggregate comprises a substrate, a second binder, and a liquid.

Disclosed herein is a transportable bio-cement comprising a desiccated microorganism package; where the microorganism package comprises one or more microorganisms; a first binder, where the first binder is produced by the microorganism; and where the microorganism has protected itself by a layer of the first binder; where the transportable bio-cement is devoid of moisture. Disclosed herein too is a method of manufacturing a transportable dry composition comprising blending together a microorganism package; a nutrient; and a liquid; activating the microorganism package to produce a first binder; subjecting the microorganism package to desiccation to form a transportable bio-cement; and blending the transportable bio-cement with an aggregate to form a bio-concrete; where the aggregate comprises a substrate, a second binder, and a liquid.

A smart roof system and method comprising cementitious sheathing sheets for a roof cover that can be installed directly onto the wood roof sheathing of a structure or home. Said cementitious sheathing sheets are laid over wood roof sheathing directly with permanent adhesive. An aluminum expansion joint is installed to serve as an expansion joint between said cementitious sheathing sheets and to provide support for solar panels.

Aluminum expansion joints have a lower lip and an upper lip, a lower lip of the aluminum expansion joints serves to support cementitious sheathing sheets over the lower lip with adhesive and create a joint directly over the wood roof sheathing. The cementitious sheathing sheets are laid on the wood roof sheathing with an adhesive designed to adhere in a permanent manner to the cementitious sheathing sheets. A next cementitious sheet is then installed into the lower lip of the aluminum expansion joints and overlap on top of the previous cementitious sheet, bonding by the permanent adhesive. The procedure is repeated forming the roof from lower elevation to higher roof elevation, thereby water will flow over the overlapping sections of cementitious sheathing sheets.

The present invention relates to dry particulate composition for forming a geopolymer, comprising an alkali metal hydroxide, an alkali metal silicate, and an aluminosilicate. The invention further relates to methods for forming geopolymers and geopolymers formed according to said methods or using the said dry particulate composition.

Red mud-based geopolymer compositions and methods of their preparation are described. The red mud-based geopolymer compositions can be cured at ambient temperatures using alkaline solutions of relatively low alkaline compound concentration compared to other geopolymer compositions. In particular, the use of a red mud previously utilized in a flue gas desulfurization process can provide high strength geopolymer compositions.

A method for making geopolymer cementitious binder compositions for cementitious products such as concrete, precast construction elements and panels, mortar, patching materials for road repairs and other repair materials, and the like is disclosed. The geopolymer cementitious compositions of some embodiments are made by mixing a synergistic mixture of thermally activated aluminosilicate mineral, calcium sulfoaluminate cement, a calcium sulfate and a chemical activator with water.

A method for stabilizing a neutralization slag of uranium associated zirconium and zirconia, and a stabilization agent used therein are disclosed. The stabilization agent includes the following components in parts by weight: a pretreatment agent of 2-8 parts, anhydrous calcium chloride of 2-6 parts, an adsorbent of 3-5 parts and a stabilizer of 4-9 parts. The stabilization agent is used to stabilize the uranium that is existed in the neutralization slag in a waste slag. The method includes the following steps: the pretreatment agent is used to alkalize and disperse the neutralization slag; soluble calcium salt is added to cement the neutralization slag; and the adsorbent and the stabilizer are used as a composite material to passivate the neutralization slag. The method has low cost, fast effectiveness, simple process, easy operation, and long-term stable remediation efficiency, which can be applied to the treatment and disposal of associated radioactive waste residues.

A method for stabilizing a neutralization slag of uranium associated zirconium and zirconia, and a stabilization agent used therein are disclosed. The stabilization agent includes the following components in parts by weight: a pretreatment agent of 2-8 parts, anhydrous calcium chloride of 2-6 parts, an adsorbent of 3-5 parts and a stabilizer of 4-9 parts. The stabilization agent is used to stabilize the uranium that is existed in the neutralization slag in a waste slag. The method includes the following steps: the pretreatment agent is used to alkalize and disperse the neutralization slag; soluble calcium salt is added to cement the neutralization slag; and the adsorbent and the stabilizer are used as a composite material to passivate the neutralization slag. The method has low cost, fast effectiveness, simple process, easy operation, and long-term stable remediation efficiency, which can be applied to the treatment and disposal of associated radioactive waste residues.