Cadmium-induced phytotoxicity and tolerance response in the low-Cd accumulator of Chinese cabbage (Brassica pekinensis L.) seedlings

Limiting the mobility and phytoavailability of cadmium in paddy-upland soils after the application of various biochar fractions and proportions

This study delves into the pivotal role of biochar particle size and addition ratio in mitigating cadmium (Cd) contamination in paddy-upland soils, with a specific focus on curbing Cd uptake by Chinese cabbage (Brassica chinensis L.) during the pivotal transition from paddy to upland cultivation. Through a meticulously designed laboratory experiment, we uncovered that biochar's adsorption capacity for soil Cd is markedly lower than its maximum adsorptive capacity as determined by adsorption kinetics, potentially due to competitive adsorption by other cationic species present in the soil. This insight underscores the critical need to optimize biochar application rates in Cd-contaminated soils to effectively modulate Cd phytoavailability. Furthermore, our findings demonstrate that biochar not only effectively converts non-residual soil Cd fractions into a more stable "residual Cd" form but also diminishes the uptake of Cd by Chinese cabbage from the soil. Notably, the application of fine biochar (Φ3 < 0.25 mm) at a 10 % application rate was particularly efficacious, reducing soil non-residual Cd concentration by 28.2 %, equivalent to approximately 1.79 mg/kg. This research introduces a novel perspective on biochar-mediated remediation of soil Cd contamination, emphasizing the critical influence of particle size and addition ratio on regulating Cd phytoavailability and enhancing food safety in agricultural soils under paddy-upland rotation cultivation affected by Cd contamination.

Removal of cadmium in aqueous solutions using a ball milling-assisted one-pot pyrolyzed iron-biochar composite derived from cotton husk

A novel iron-biochar composite adsorbent was produced via ball milling-assisted one-pot pyrolyzed BM-nZVI-BC 800. Characterization proved that nano zero valent iron was successfully embedded in the newly produced biochar, and the nZVI payload was higher than that of traditional one-pot pyrolyzed methods. BM-nZVI-BC 800 provided a high adsorption performance of cadmium reaching 96.40 mg·g^-1 during batch testing. Alkaline conditions were beneficial for cadmium removal of BM-nZVI-BC 800. The pseudo-second-order kinetic model and Langmuir isotherm fitted better, demonstrating that the Cd adsorption on the BM-nZVI-BC 800 was a chemical and surface process. The intraparticle diffusion controlled the adsorption of BM-nZVI-BC 800. The physisorption dominated by high specific surface area and mesoporous structure was the primary mechanism in the removal of cadmium, though electrostatic attraction and complexation also played a secondary role in cadmium adsorption. Compared to adsorbents prepared by more traditional methods, the efficiencies of the ball milling-assisted one-pot pyrolyzed method appears superior.