The disclosure relates to fertilizer coating compositions and methods for making thereof. The fertilizer coating comprises a decarboxylated rosin acid (DCR) component, optional bitumen and other additives. The DCR has a Kb value of 25-90, a density of 0.9 to 1.0 g/cm.sup.3 at 20° C., an aniline point of 3-40° C., and an acid value of <50 mg KOH/g. The fertilizer coated with the coating composition has a reduction in dust level of >25% after 2 weeks of aging compared to a fertilizer not having the coating composition disposed thereon, according to Dust Level Measurement Test.

The disclosure relates to fertilizer coating compositions and methods for making thereof. The fertilizer coating comprises a decarboxylated rosin acid (DCR) component, optional bitumen and other additives. The DCR has a Kb value of 25-90, a density of 0.9 to 1.0 g/cm.sup.3 at 20° C., an aniline point of 3-40° C., and an acid value of <50 mg KOH/g. The fertilizer coated with the coating composition has a reduction in dust level of >25% after 2 weeks of aging compared to a fertilizer not having the coating composition disposed thereon, according to Dust Level Measurement Test.

A method of preparing ferric phosphate from iron-containing waste, including: step a) providing a ferric chloride-containing mixture solution obtained from acidolysis of iron-containing waste; step b) adjusting pH of the ferric chloride-containing mixture solution to satisfy 0<pH≤2 and Fe.sup.3+ concentration to 10-80 g/L with an alkaline compound and water, to obtain an iron source solution; step c) mixing and reacting the iron source solution obtained from the step b) with a solution of calcium dihydrogen phosphate in a molar ratio of P to Fe of 1 : 1-1.8, to obtain a slurry with a pH of 0.2-2; and step d) performing aging and crystal transformation on the slurry, to obtain ferric phosphate. A battery-grade ferric phosphate with high purity and good product quality can be obtained without the need for deep purification of raw materials.

A method of preparing ferric phosphate from iron-containing waste, including: step a) providing a ferric chloride-containing mixture solution obtained from acidolysis of iron-containing waste; step b) adjusting pH of the ferric chloride-containing mixture solution to satisfy 0<pH≤2 and Fe.sup.3+ concentration to 10-80 g/L with an alkaline compound and water, to obtain an iron source solution; step c) mixing and reacting the iron source solution obtained from the step b) with a solution of calcium dihydrogen phosphate in a molar ratio of P to Fe of 1 : 1-1.8, to obtain a slurry with a pH of 0.2-2; and step d) performing aging and crystal transformation on the slurry, to obtain ferric phosphate. A battery-grade ferric phosphate with high purity and good product quality can be obtained without the need for deep purification of raw materials.

formaldehyde-based polymer composite is coated on a surface of the biodegradable polymer fabric, and is embedded in meshes of the biodegradable polymer fabric. There is intermolecular hydrogen-bond interaction between the biodegradable urea-formaldehyde-based polymer composite and the biodegradable polymer fabric.

formaldehyde-based polymer composite is coated on a surface of the biodegradable polymer fabric, and is embedded in meshes of the biodegradable polymer fabric. There is intermolecular hydrogen-bond interaction between the biodegradable urea-formaldehyde-based polymer composite and the biodegradable polymer fabric.

Disclosed herein are mineral-based composites that comprise gypsum, syngenite, brucite and a hydrated magnesium sulphate mineral, and which are adapted to degrade when buried. Also disclosed herein are mineral mixtures which can be used to produce the mineral-based composites, as well as products, such as plantable containers, formed from the mineral-based composites and which degrade when buried.

Disclosed herein are mineral-based composites that comprise gypsum, syngenite, brucite and a hydrated magnesium sulphate mineral, and which are adapted to degrade when buried. Also disclosed herein are mineral mixtures which can be used to produce the mineral-based composites, as well as products, such as plantable containers, formed from the mineral-based composites and which degrade when buried.

A bacterial product may comprise strains Azospirillum oryzae AO.sub.512, Azospirillum lipoferum AL.sub.20, Pantoea dispersa PD.sub.2, Bacillus subtilis TU.sub.2, Lysinibacillus sphaericus 3S and Paenibacillus polymyxa SR.sub.17, in a total minimal concentration of 10.sup.8 CFU/g (Colony forming Units). These bacteria may be attached to an insoluble granular carrier formed of a mixture of natural clays and minerals. This formulation may preserve the viability of the microorganism for a long time while in storage, as well as after its application on the field. These microorganisms, as PGPR, may be capable of fixing atmospheric nitrogen, solubilize phosphates, potassium, as well as other minerals immobilized in the soil, which allows for a drastic reduction, and even for a complete elimination, of conventional fertilization methods. These bacteria are not harmful in any sense neither to human beings nor the environment.

A bacterial product may comprise strains Azospirillum oryzae AO.sub.512, Azospirillum lipoferum AL.sub.20, Pantoea dispersa PD.sub.2, Bacillus subtilis TU.sub.2, Lysinibacillus sphaericus 3S and Paenibacillus polymyxa SR.sub.17, in a total minimal concentration of 10.sup.8 CFU/g (Colony forming Units). These bacteria may be attached to an insoluble granular carrier formed of a mixture of natural clays and minerals. This formulation may preserve the viability of the microorganism for a long time while in storage, as well as after its application on the field. These microorganisms, as PGPR, may be capable of fixing atmospheric nitrogen, solubilize phosphates, potassium, as well as other minerals immobilized in the soil, which allows for a drastic reduction, and even for a complete elimination, of conventional fertilization methods. These bacteria are not harmful in any sense neither to human beings nor the environment.