Distinct interactions of pig and cow manure-derived colloids with TiO2 nanoparticles and their impact on stability and transport

“…Further, the transport of the pristine TiO 2 was enhanced to a similar extent as the transport of the mulch-released TiO 2 (Figure D and Table S3), when the pristine TiO 2 particles cotransported with the compost residues. These results imply that the higher mobility of the mulch-released TiO 2 in the sand columns can be attributed to steric repulsion imposed by the presence of humic acid like substances in compost residues, consistent with previous studies. , …”

“…Similarly, Yang et al found that the blocking effect was accountable for the increased mobility of bacteria in sand columns preflushed with humic acid (1 mg L –1 ). Moreover, humic acid can promote colloid transport by adsorbing onto colloid surfaces and imposing steric interactions. , Indeed, the mulch-released TiO 2 particles appeared to be covered with compost residues (Figure S1A), and when steric interactions were included into the DLVO calculations, the energy barrier substantially increased between the TiO 2 particles and the sand–water interface (Figure S8C), suggesting unfavorable attachment conditions. Further, the transport of the pristine TiO 2 was enhanced to a similar extent as the transport of the mulch-released TiO 2 (Figure D and Table S3), when the pristine TiO 2 particles cotransported with the compost residues.…”

“…Further analysis with single-particle mass spectrometry (Figure 4) confirmed that the dislodged particles indeed contained TiO 2 particles, and the mass spectra of individual Ti-signaled particles matched those of pristine TiO 2 particles (Figure 4A). The majority of the released particles from the meshbags, however, was composed of compost material, as indicated by the dominance of 23 Na + , 27 Al + , 39 K + , and 44 SiO + /CO 2 + in the overall mass spectrum (Figure 4A, top panel). The size distribution of the released particles was similar to that of the pristine TiO 2 (Figure 4B).…”

Enhanced Transport of TiO₂ in Unsaturated Sand and Soil after Release from Biodegradable Plastic during Composting

“…Further, the transport of the pristine TiO 2 was enhanced to a similar extent as the transport of the mulch-released TiO 2 (Figure D and Table S3), when the pristine TiO 2 particles cotransported with the compost residues. These results imply that the higher mobility of the mulch-released TiO 2 in the sand columns can be attributed to steric repulsion imposed by the presence of humic acid like substances in compost residues, consistent with previous studies. , …”

“…Similarly, Yang et al found that the blocking effect was accountable for the increased mobility of bacteria in sand columns preflushed with humic acid (1 mg L –1 ). Moreover, humic acid can promote colloid transport by adsorbing onto colloid surfaces and imposing steric interactions. , Indeed, the mulch-released TiO 2 particles appeared to be covered with compost residues (Figure S1A), and when steric interactions were included into the DLVO calculations, the energy barrier substantially increased between the TiO 2 particles and the sand–water interface (Figure S8C), suggesting unfavorable attachment conditions. Further, the transport of the pristine TiO 2 was enhanced to a similar extent as the transport of the mulch-released TiO 2 (Figure D and Table S3), when the pristine TiO 2 particles cotransported with the compost residues.…”

“…Further analysis with single-particle mass spectrometry (Figure 4) confirmed that the dislodged particles indeed contained TiO 2 particles, and the mass spectra of individual Ti-signaled particles matched those of pristine TiO 2 particles (Figure 4A). The majority of the released particles from the meshbags, however, was composed of compost material, as indicated by the dominance of 23 Na + , 27 Al + , 39 K + , and 44 SiO + /CO 2 + in the overall mass spectrum (Figure 4A, top panel). The size distribution of the released particles was similar to that of the pristine TiO 2 (Figure 4B).…”

Enhanced Transport of TiO₂ in Unsaturated Sand and Soil after Release from Biodegradable Plastic during Composting

“…To evaluate the influence of protein on the stability of TiO 2 , 25 mg L −1 TiO 2 suspension was prepared by ultrasonic bath for 30 min, which was mixed with certain concentrations (0, 2, 4, 8, and 16 mg L −1 ) of BSA in 1 mM NaCl solution or with 8 mg L −1 BSA, OVA, and A-LA in various IS (1, 5 and 10 mM). The absorbance ( A ) of TiO 2 with the protein mixture was monitored using a UV-vis spectrophotometer at a wavelength of 285 nm, 56 which was measured every 2 minutes during a 2 h duration.…”

“…The packing procedures of the quartz sand column were followed as described in previous studies. 56,57 About 95.5 g of clean quartz sand were wet-packed into a 12.4 cm long and 2.6 cm diameter stainless-steel column with a bulk density of 1.45 ± 0.02 g cm −3 and a porosity of 0.45 ± 0.01. The columns were flushed upward using a peristaltic pump (DHL-A, Huxi, China) at a flow rate of 1 mL min −1 .…”

Coupled impact of proteins with different molecular weights and surface charges on TiO₂ mobility

Goethite-enriched biochar mitigates soil emissions of CO2 during arsenic passivation: Effect and mechanisms