A refractory material for forming a refractory product includes a refractory component and a taggant having an amorphous or a crystalline solid dispersed within the refractory material. The taggant is configured to be distinguishable from the refractory component after heating of the refractory product between 300 degrees F. and 3500 degrees F. A method of reclaiming refractory material of a refractory lining constructed from different types of refractory products, the refractory lining having been subjected to temperatures in excess of 300 degrees F., includes demolishing the refractory lining to produce a mixture of refractory pieces of different types of refractory products. The mixture of refractory pieces is analyzed to detect the presence of one or more taggants, and the refractory pieces are sorted into groups based on the detected one or more taggants.

A method of reducing the swell potential of an expansive clay mineral. The method includes (a) carrying out a forcefield-modified molecular level simulation to determine an amount of a swelling reduction agent to be incorporated into the expansive clay mineral to form a swelling reduction agent incorporated expansive clay mineral with a reduced swell potential S.sub.i(ECM) that is no greater than a pre-set level T, wherein the swelling reduction agent comprises at least one cementation material of calcite, gypsum, and potassium chloride and/or at least one exchangeable cation of K.sup.+, Ca.sup.2+, and Mg.sup.2+, and wherein the forcefield-modified molecular level simulation comprises molecular mechanics, molecular dynamics, and Monte Carlo simulation techniques configured to simulate the reduced swell potential S.sub.i(ECM), and (b) incorporating the amount of the swelling reduction agent into the expansive clay mineral to form the swelling reduction agent incorporated expansive clay mineral.

A method of reducing the swell potential of an expansive clay mineral. The method includes (a) carrying out a forcefield-modified molecular level simulation to determine an amount of a swelling reduction agent to be incorporated into the expansive clay mineral to form a swelling reduction agent incorporated expansive clay mineral with a reduced swell potential S.sub.i(ECM) that is no greater than a pre-set level T, wherein the swelling reduction agent comprises at least one cementation material of calcite, gypsum, and potassium chloride and/or at least one exchangeable cation of K.sup.+, Ca.sup.2+, and Mg.sup.2+, and wherein the forcefield-modified molecular level simulation comprises molecular mechanics, molecular dynamics, and Monte Carlo simulation techniques configured to simulate the reduced swell potential S.sub.i(ECM), and (b) incorporating the amount of the swelling reduction agent into the expansive clay mineral to form the swelling reduction agent incorporated expansive clay mineral.

A method of reducing the swell potential of an expansive clay mineral. The method includes (a) carrying out a forcefield-modified molecular level simulation to determine an amount of a swelling reduction agent to be incorporated into the expansive clay mineral to form a swelling reduction agent incorporated expansive clay mineral with a reduced swell potential S.sub.i(ECM) that is no greater than a pre-set level T, wherein the swelling reduction agent comprises at least one cementation material of calcite, gypsum, and potassium chloride and/or at least one exchangeable cation of K.sup.+, Ca.sup.2+, and Mg.sup.2+, and wherein the forcefield-modified molecular level simulation comprises molecular mechanics, molecular dynamics, and Monte Carlo simulation techniques configured to simulate the reduced swell potential S.sub.i(ECM), and (b) incorporating the amount of the swelling reduction agent into the expansive clay mineral to form the swelling reduction agent incorporated expansive clay mineral.

Systems and methods are provided for materials, methods for making such materials, and apparatus and systems using such materials, which may be used for climate control, that is, cooling or warming using water evaporation and condensation to efficiently cool or warm living spaces, devices, and equipment with or without electricity and in any climate. The materials may comprise clay, carbon, and a metal, and may be formed, treated with water or other substances, and baked. The materials may be incorporated into apparatus and systems that provide cooling and/or heating.

A method of reducing the swell potential of an expansive clay mineral. The method includes (a) carrying out a forcefield-modified molecular level simulation to determine an amount of a swelling reduction agent to be incorporated into the expansive clay mineral to form a swelling reduction agent incorporated expansive clay mineral with a reduced swell potential S.sub.i(ECM) that is no greater than a pre-set level T, wherein the swelling reduction agent comprises at least one cementation material of calcite, gypsum, and potassium chloride and/or at least one exchangeable cation of K.sup.+, Ca.sup.2+, and Mg.sup.2+, and wherein the forcefield-modified molecular level simulation comprises molecular mechanics, molecular dynamics, and Monte Carlo simulation techniques configured to simulate the reduced swell potential S.sub.i(ECM), and (b) incorporating the amount of the swelling reduction agent into the expansive clay mineral to form the swelling reduction agent incorporated expansive clay mineral.

Material, use thereof and method to manufacture said material; wherein the material is porous and has: a total porosity ranging from 50% to 80%, in particular from 60% to 70%; interconnected pores; at least a part made of a hydrophilic material, in particular at least a part of the inner surfaces of the pores is made of a hydrophilic material; a permeability coefficient (k) greater than 106 m/sec; and wherein, in a given volume of the material (1), the total volume of pores with a diameter ranging from 0.1.Math. to approximately 0.3 nm is at least greater than 15% of the total volume of the pores, preferably it ranges from 15 to 36%.

A composition for a refractory material comprising a base mixture having a composition in oxide (mol %) as follows: SiO2 between 69% and 73%; Al2O3 between 22% and 28%; TiO2 between 0.4% and 1%; Fe2O3 between 0.2% and 1%; CaO between 0.1% and 1%; MgO between 0.1% and 1%; K.sub.2O between 0.5% and 2%; Na.sub.2O between 0.1% and 0.5%; and comprising a filler mixture comprising at least one from between a schamotte and a smelting agent.

A composition for a refractory material comprising a base mixture having a composition in oxide (mol %) as follows: SiO2 between 69% and 73%; Al2O3 between 22% and 28%; TiO2 between 0.4% and 1%; Fe2O3 between 0.2% and 1%; CaO between 0.1% and 1%; MgO between 0.1% and 1%; K.sub.2O between 0.5% and 2%; Na.sub.2O between 0.1% and 0.5%; and comprising a filler mixture comprising at least one from between a schamotte and a smelting agent.

Described herein are sintered spheres, obtained from red mud, comprising at least aluminium oxide, iron oxides, silicon oxide, and titanium oxide, characterized in that the roundness and the sphericity of the sintered spheres is higher than 0.6.

Described is further a process for the production of sintered spheres, comprising the following steps: a) providing red mud, being a residue from alumina production, b) optionally adjusting the pH value of the red mud to a value lower than 9, c) granulating the red mud from step b) under continuous drying, d) sintering the granulate from step c).

Described herein is also the use of sintered spheres as proppant in fracking processes or as aggregate or lightweight fine aggregate (LWFA) for construction purposes or for geological solidification processes.