An ozonation-based method for producing a cementitious material comprises the steps of: (1) mixing a flue gas with an ozone-containing gas to form a mixed flue gas; and introducing the mixed flue gas into an absorption tower, where the mixed flue gas undergoes dry desulfurization and denitrification by reacting with a powdered desulfurizing and denitrificating agent and becomes a treated flue gas; (2) subjecting the treated flue gas to dust removal to generate by-products; and (3) uniformly mixing raw materials that comprise the first by-product, magnesium oxide, fly ash and an additive to give a cementitious material, wherein on the basis of 100 parts by weight of the cementitious material, the first by-product is 20-60 parts by weight, magnesium oxide is 16-33 parts by weight, the fly ash is 15-35 parts by weight, and the additive is 1-15 parts by weight.

An ozonation-based method for producing a cementitious material comprises the steps of: (1) mixing a flue gas with an ozone-containing gas to form a mixed flue gas; and introducing the mixed flue gas into an absorption tower, where the mixed flue gas undergoes dry desulfurization and denitrification by reacting with a powdered desulfurizing and denitrificating agent and becomes a treated flue gas; (2) subjecting the treated flue gas to dust removal to generate by-products; and (3) uniformly mixing raw materials that comprise the first by-product, magnesium oxide, fly ash and an additive to give a cementitious material, wherein on the basis of 100 parts by weight of the cementitious material, the first by-product is 20-60 parts by weight, magnesium oxide is 16-33 parts by weight, the fly ash is 15-35 parts by weight, and the additive is 1-15 parts by weight.

The subject matter discloses a plastic composition comprising a first component and a second component, the first component comprising an organic element and a thermoplastic element and the second component comprising cross-linked hydrocarbon elastomers. The subject matter further discloses a process comprising mixing while heating under shear forces a first component comprising organic material and thermoplastic material with a second component comprising cross-linked hydrocarbon elastomers; to obtain a melt; processing the melt, the processing comprises at least cooling the melt to obtain a plastic composition comprising: organic element; thermoplastic element; and at least one cross-linked hydrocarbon elastomer element.

The subject matter discloses a plastic composition comprising a first component and a second component, the first component comprising an organic element and a thermoplastic element and the second component comprising cross-linked hydrocarbon elastomers. The subject matter further discloses a process comprising mixing while heating under shear forces a first component comprising organic material and thermoplastic material with a second component comprising cross-linked hydrocarbon elastomers; to obtain a melt; processing the melt, the processing comprises at least cooling the melt to obtain a plastic composition comprising: organic element; thermoplastic element; and at least one cross-linked hydrocarbon elastomer element.

The subject matter discloses a plastic composition comprising a first component and a second component, the first component comprising an organic element and a thermoplastic element and the second component comprising cross-linked hydrocarbon elastomers. The subject matter further discloses a process comprising mixing while heating under shear forces a first component comprising organic material and thermoplastic material with a second component comprising cross-linked hydrocarbon elastomers; to obtain a melt; processing the melt, the processing comprises at least cooling the melt to obtain a plastic composition comprising: organic element; thermoplastic element; and at least one cross-linked hydrocarbon elastomer element.

Method for preparing a sustainable construction material, the method including: combining construction waste, food waste comprising calcium, and water thereby forming a waste mixture; optionally moulding the waste mixture; and contacting the waste mixture with CO.sub.2 under conditions in which at least a portion of the calcium present in the waste mixture is converted to calcium carbonate thereby forming a treated waste mixture thereby forming the sustainable construction material.

Method for preparing a sustainable construction material, the method including: combining construction waste, food waste comprising calcium, and water thereby forming a waste mixture; optionally moulding the waste mixture; and contacting the waste mixture with CO.sub.2 under conditions in which at least a portion of the calcium present in the waste mixture is converted to calcium carbonate thereby forming a treated waste mixture thereby forming the sustainable construction material.

A method for recycling electronic waste may method comprise receiving electronic waste from an electronic waste-generating entity, separating components of the electronic waste into valuable recyclable material, hazardous material, and disposable non-hazardous material, creating a plurality of building material units comprising the disposable non-hazardous material, and sending at least a portion of the plurality of building material units back to the electronic waste-generating entity.

A method for recycling electronic waste may method comprise receiving electronic waste from an electronic waste-generating entity, separating components of the electronic waste into valuable recyclable material, hazardous material, and disposable non-hazardous material, creating a plurality of building material units comprising the disposable non-hazardous material, and sending at least a portion of the plurality of building material units back to the electronic waste-generating entity.

A method for preparing ceramsite by using municipal sludge as raw material, including the following specific steps: drying; preparing ingredients including raw sludge, fly ash, kaolinite, steelmaking slag, zeolite, hematite, calcareous shale, waste incineration fly ash, Fe.sub.2O.sub.3, waste glass, calcium carbonate, sodium lauryl sulfate, and sodium benzoate; mixing and stirring uniformly, and putting the stirred materials into a granulating machine for granulation; drying and preheating the material pellets after granulation, and then quickly transferring to a sintering device for first sintering at a low temperature and then sintering at a high temperature; crushing large chunks of the cooled materials; and separating and screening the crushed materials. The method of the present invention reduces the generation of the large chunks of the cooled materials in the obtained ceramsite, thereby reducing the subsequent crushing work and saving energy consumption accordingly.