A composite member includes a matrix part including an inorganic substance, and an organic infrared absorbing material present in a dispersed state inside the matrix part. The composite member has a porosity of 20% or less in a section of the matrix part. A heat generation device includes the composite member, and an infrared light source for irradiating the composite member with infrared rays. A building member and a light emitting device each include the composite member, or the heat generation device.

A composite member includes a matrix part including an inorganic substance, and an organic dye present in a dispersed state inside the matrix part. The composite member has a porosity of 20% or less in a section of the matrix part. A construction member and a decoration member each include the composite member.

A composite member includes a matrix part including an inorganic substance, and an organic dye present in a dispersed state inside the matrix part. The composite member has a porosity of 20% or less in a section of the matrix part. A construction member and a decoration member each include the composite member.

Reinforcing filaments or fibers, such as aromatic polyamide (aramid) fibers, can be reliably measured and consistently mixed into asphalt cement concrete by soaking the fibers in a wetting agent, then severing them to a desired length, and mixing the segments with other ACC ingredients. The wetting agent holds the fibers together loosely, so they can be distributed more uniformly throughout the ACC without clumping. The wetting agent soaks into the ACC mixture and/or evaporates, leaving the reinforcing fibers behind.

Reinforcing filaments or fibers, such as aromatic polyamide (aramid) fibers, can be reliably measured and consistently mixed into asphalt cement concrete by soaking the fibers in a wetting agent, then severing them to a desired length, and mixing the segments with other ACC ingredients. The wetting agent holds the fibers together loosely, so they can be distributed more uniformly throughout the ACC without clumping. The wetting agent soaks into the ACC mixture and/or evaporates, leaving the reinforcing fibers behind.

A method for drying building material slabs, in particular slabs containing gypsum, which are guided in floors (15) through an device divided into a drying pre-zone (2) and drying chambers and in which the slabs are brought into contact with drying air, characterized in that drying air is applied from the drying pre-zone (2) to the slabs in an area (1) arranged upstream of the pre-zone (2) and enclosed at least, with respect to the conveying direction of the boards, on both longitudinal sides and on the upper side.

Provided herein are manufacturing processes that include (1) subjecting precursor-containing solids to dissolution under acoustic perturbation to yield an initial slurry including dissolved precursors; (2) subjecting the initial slurry to hydrothermal synthesis to yield a subsequent slurry including siliceous solids formed from the dissolved precursors; and (3) subjecting the subsequent slurry to cementation to yield a cemented siliceous solid. Also provided herein are cemented siliceous solids formed by the manufacturing processes.

Methods of conducting ureolysis-induced calcium carbonate precipitation with a heat-treated cell preparation, methods for preparing the heat-treated cell preparation, and related materials. The methods of conducting ureolysis-induced calcium carbonate precipitation include precipitating calcium carbonate at a location by introducing urea, calcium, and a heat-treated cell preparation comprising active urease enzyme to the location. The urease enzyme hydrolyzes the urea to ammonium carbonate, and the calcium reacts with the carbonate to form a calcium carbonate precipitate at the location. The methods of preparing the heat-treated cell preparation include heating a urease-producing cell preparation at a temperature and for a time sufficient to inactivate at least a portion of the cells in the urease-producing cell preparation while maintaining at least some urease activity of urease made by the cells in the urease-producing cell preparation

Methods of conducting ureolysis-induced calcium carbonate precipitation with a heat-treated cell preparation, methods for preparing the heat-treated cell preparation, and related materials. The methods of conducting ureolysis-induced calcium carbonate precipitation include precipitating calcium carbonate at a location by introducing urea, calcium, and a heat-treated cell preparation comprising active urease enzyme to the location. The urease enzyme hydrolyzes the urea to ammonium carbonate, and the calcium reacts with the carbonate to form a calcium carbonate precipitate at the location. The methods of preparing the heat-treated cell preparation include heating a urease-producing cell preparation at a temperature and for a time sufficient to inactivate at least a portion of the cells in the urease-producing cell preparation while maintaining at least some urease activity of urease made by the cells in the urease-producing cell preparation

A water-repellent member includes a matrix part including an inorganic substance including at least one of a metal oxide or a metal hydroxide, and a water-repellent resin present in a dispersed state inside the matrix part. The water-repellent member has a porosity of 20% or less in a section of the matrix part. A building member and a wet room member each include the water-repellent member.