Co-pyrolysis of rice straw with industrial wastes: Waste disposal and environmental remediation.

To reduce waste volumes and recover valuable products, char was synthesized via co-pyrolysis of rice straw (RS) with spent tires, sulfur wastes, and CO2. The inclusion of wastes and CO2 in pyrolysis of RS was hypothesized to enhance the sorption ability of char for various contaminants, including 2,4-dinitrotoluene (DNT), 2,4-dichlorophenol (DCP), lead, barium, chromate (CrO42-), and selenate (SeO42-). Using a lab-scale electrical furnace, the co-pyrolysis was conducted, and the soprtion capacity of char was evaluated via a series of batch sorption experiments. The maximum sorption capacity of spent tire-RS char for DNT was 16.8 ± 0.2 mg g-1, much higher than that of RS biochar (10.1 ± 0.3 mg g-1) due to increasing carbon content from the spent tires. The sorption of DCP to the spent tire-RS char was also enhanced via hydrophobic sorption to carbon residues, although not to the same degree of DNT due to deprotonation of the DCP. Compared with RS biochar, co-pyrolysis with raw sulfur wastes and CO2 enhanced sorption of lead, barium, and chromate, which can be attributed to increased cation and anion exchange capacities resulting from developments of oxygen or sulfur-containing functional groups. Sorption of selenate was strongly affected by pH. The results suggest that co-pyrolysis of agricultural and industrial wastes and CO2 is a promising option for the final waste disposal and the production of valuable char, which can be selectively customized for various types of contaminants as sorbents.

Upgrading biochar via co-pyrolyzation of agricultural biomass and polyethylene terephthalate wastes.

Spent polyethylene terephthalate (PETE) bottles were collected and co-pyrolyzed with rice straw (RS) to examine the characteristics and performance of biochar as a sorbent for various types of U.S. EPA priority pollutants, including 2,4-dinitrotoluene (DNT), 2,4-dichlorophenol (DCP), Pb, chromate (CrO4 2-), and selenate (SeO4 2-). During sorption of contaminants to PETE/RS-derived biochar, PETE residues from pyrolysis, pH, and pyrolysis temperature greatly affected the sorption process. Depending on the types of contaminants and experimental conditions, co-pyrolysis of PETE and RS may enhance the sorption of contaminants through different sorption mechanisms, including hydrophobicity, electrostatic force, ion exchange, surface complexation, and surface precipitation. Unlike other contaminants, selenate was reductively transformed by delocalized electrons from the graphitic structure in biochar. Our results strongly suggest that co-pyrolysis of PETE and agricultural wastes may be favorable to enhance the properties of biochar. In addition to syn-gas and bio-oil from co-pyrolysis, biochar may be a valuable by-product for commercial use.

Selenium-enriched garlic and cabbage as a dietary selenium source for broilers.

This study determined the selenium (Se) bioavailability from Se-enriched garlic and cabbage using broiler chickens. Se-enriched garlic (18.5 mg of Se/kg) and cabbage (101.5 mg of Se/kg) were produced by soil enrichment using selenate. Conventional and Se-enriched garlic and cabbage were dried, ground, and added to broiler chick diets. Ninety-six broiler chickens at 1 day of age were assigned to four dietary treatments: NC (cabbage + garlic), PC (cabbage + garlic + selenomethionine, 0.5 mg of Se/kg of diet), GS (cabbage + Se-enriched garlic, 0.5 mg of Se/kg of diet), and CS (garlic + Se-enriched cabbage, 0.5 mg of Se/kg of diet), with six replicates per treatment and four birds per cage. Birds were fed the experimental diets for 4 weeks and slaughtered to obtain blood and tissues: white (breast) muscle, dark (thigh) muscle, liver, and feathers. All excreta were collected weekly, dried, and ground for Se analysis. Bird weight gain and feed intake were measured weekly. Total Se content and glutathione peroxidase (GPX) activity in liver and plasma were measured. Total liver Se content of the PC birds (0.876 mg of Se/kg) was the highest (P < .05). The CS (0.693 mg of Se/kg) and GS (0.627 mg of Se/kg) birds had higher (P < .05) total liver Se than the NC birds (0.514 mg of Se/kg). Plasma GPX activity of the PC birds was highest (P < .05), and that of CS and GS birds was higher (P < .05) than the NC birds. Liver GPX activity of the PC birds was higher (P < .05) than all other treatments. Bioavailability of Se to broiler chickens was not different (P > .05) among PC (65.2%), CS (61.2%), and GS (70.7%) birds. This study indicates that the Se from Se-enriched garlic and cabbage is highly bioavailable and can potentially be beneficial in enhancing Se status and GPX activity.