Compositions of matter for use as a roof coating are provided. The roof coating can be applied to any suitable roof of any building. When applied to a roof, the roof coating insulates the building's interior from some of the sun's thermal energy, which would otherwise radiate into the building and raise the interior temperature. The roof coating can therefore reduce energy consumption involved in cooling the building's interior. The roof coating demonstrates advantageous thermal insulation properties (e.g., low thermal conductivity) over a wide range of temperatures and when applied with minimal thickness. The provided roof coating demonstrates high reflectance, high emissivity, low thermal conductivity, low flame spread, high solar reflectance index (SRI) in the range of 100 to 120, and acts as a sealer and waterproofer, which all contribute to its desirable properties for use as a thermally insulating roof coating.

A vehicle coating to thermally insulate the vehicle's interior is provided. The vehicle coating may be applied to the exterior (e.g., roof) of any suitable moving vehicle, such as a bus, RV, delivery truck, construction vehicle (e.g., cement mixer), train car. When applied to a vehicle's exterior, the vehicle coating provides the benefit of insulating the vehicle's interior from some of the sun's thermal energy, which would otherwise radiate into the vehicle and increase the interior temperature. The vehicle coating demonstrates advantageous thermal insulation properties (e.g., low thermal conductivity) over a wide range of temperatures and when applied with minimal thickness. The provided vehicle coating demonstrates high reflectance, high emissivity, low thermal conductivity, and high solar reflectance index (SRI), and is suitable for high vibration high uplift winds, which all contribute to its desirable properties for use as a thermally insulating vehicle coating.

A vehicle coating to thermally insulate the vehicle's interior is provided. The vehicle coating may be applied to the exterior (e.g., roof) of any suitable moving vehicle, such as a bus, RV, delivery truck, construction vehicle (e.g., cement mixer), train car. When applied to a vehicle's exterior, the vehicle coating provides the benefit of insulating the vehicle's interior from some of the sun's thermal energy, which would otherwise radiate into the vehicle and increase the interior temperature. The vehicle coating demonstrates advantageous thermal insulation properties (e.g., low thermal conductivity) over a wide range of temperatures and when applied with minimal thickness. The provided vehicle coating demonstrates high reflectance, high emissivity, low thermal conductivity, and high solar reflectance index (SRI), and is suitable for high vibration high uplift winds, which all contribute to its desirable properties for use as a thermally insulating vehicle coating.

A new and innovative fireproof coating is provided. The fireproof coating exhibits high heat insulation combined with a low flame spread and low smoke density. The fireproof coating can be applied to any suitable structure for which fireproofing is beneficial. An advantage of the fireproof coating is low weight and high flexibility compared to conventional fireproofing technologies while still providing equivalent or better fireproofing properties. The provided fireproof coating has a low thermal conductivity and high emissivity, each of which provide the coating with desirable fireproofing properties. The fireproof coating also demonstrates its advantageous fireproofing properties over a wide range of temperatures and adds minimal thickness to the structures on which it is applied while still providing equivalent or better fireproofing properties as other, thicker fireproof materials.

A new and innovative fireproof coating is provided. The fireproof coating exhibits high heat insulation combined with a low flame spread and low smoke density. The fireproof coating can be applied to any suitable structure for which fireproofing is beneficial. An advantage of the fireproof coating is low weight and high flexibility compared to conventional fireproofing technologies while still providing equivalent or better fireproofing properties. The provided fireproof coating has a low thermal conductivity and high emissivity, each of which provide the coating with desirable fireproofing properties. The fireproof coating also demonstrates its advantageous fireproofing properties over a wide range of temperatures and adds minimal thickness to the structures on which it is applied while still providing equivalent or better fireproofing properties as other, thicker fireproof materials.

A method of treating a subterranean formation comprising: forming a treatment fluid by adding a desired volume of a liquid concentrate suspension to at least a base fluid, wherein the treatment fluid comprises the liquid concentrate suspension and the base fluid, and wherein the liquid concentrate suspension comprises: (A) water; (B) an additive; and (C) a magnesium silicate clay, wherein the clay increases the viscosity of the water, wherein the liquid concentrate suspension is stable for a time period of at least 2 weeks; and introducing the treatment fluid into the subterranean formation.

A method of treating a subterranean formation comprising: forming a treatment fluid by adding a desired volume of a liquid concentrate suspension to at least a base fluid, wherein the treatment fluid comprises the liquid concentrate suspension and the base fluid, and wherein the liquid concentrate suspension comprises: (A) water; (B) an additive; and (C) a magnesium silicate clay, wherein the clay increases the viscosity of the water, wherein the liquid concentrate suspension is stable for a time period of at least 2 weeks; and introducing the treatment fluid into the subterranean formation.

A variety of systems, methods and compositions are disclosed for cementing in subterranean formations. Embodiments may include the use of slag co-grind in well cementing operations.

A variety of systems, methods and compositions are disclosed for cementing in subterranean formations. Embodiments may include the use of slag co-grind in well cementing operations.

A powder essentially composed of aggregates based on boron nitride, the powder exhibiting an overall chemical composition, as percentages by weight, including between 40 and 45% of boron, between 53 and 57% of nitrogen, less than 400 ppm by weight of calcium, less than 5%, in total, of other elements and more than 90% of boron nitride, limit included, as percentage by weight and on the basis of the combined crystalline phases, a mean circularity of greater than or equal to 0.90, a median pore size of less than or equal to 1.5 m and an apparent porosity of less than or equal to 55%.