As a cheap and accessible electronic repository, microscale zerovalent iron (mZVI) has up-and-coming applications in uranium wastewater disposal. Yet, its reactivity is still constrained by the inert oxide shell. To overcome this shortcoming, a ball milling technique was used to prepare sulfidated microscale zerovalent (S-mZVIbm) for treating uranium wastewater. Under ambient conditions, the oxide layer formed on the surface of mZVIbm due to the passivation of dissolved oxygen was replaced by the sulfide layer of S-mZVIbm. Theoretical calculations and characterization results showed that the sulfide layer not only enhanced surface coordination and enrichment of uranium, but also promoted the electron transfer from the iron core to the surface. The work function of S-mZVIbm was lower than that of mZVIbm, emphasizing the excellent electron-donating potential exhibited by S-mZVIbm. The calculated apparent rate constant k2 (4.47 × 10-3 g·mg·min-1) and removal efficiency (90.0%) of S-mZVIbm within 5 h were 20.1 and 7.5 times larger than those of mZVIbm within 10 h, respectively. Moreover, the content of uranium could be decreased to levels below the standard limit value for drinking water quality (30 μg L-1) with S-mZVIbm in real uranium wastewater. These findings offer novel insights into treating uranium wastewater through ZVI-based technology.
Li et al. (Sat,) studied this question.
Synapse has enriched 5 closely related papers on similar clinical questions. Consider them for comparative context: