摘要

Nano-Al-13 clusters have the potential to form and remain in a coagulation process, but cannot be directly traced by traditional instrumental techniques in real time since there is only a trace concentration after being dosed. In this study, an optimized electrospray ionization mass spectrometry (ESI-MS) method was introduced for the first time to determine the coagulation pathways when using AlCl3 (monomeric Al, i.e., Al-m) and polymeric aluminum chloride (PACl) as coagulants. The transformation mechanisms of Al clusters, including Al-m, oligomeric Al (Al-o), Al-13 and transient Al (Al-ts), were clearly elucidated using statistical analysis and a real-time tracking experiment. The nano-Al-13 clusters could be detected in the coagulation batch experiment conducted using AlCl3 as the coagulant. Moreover, using a statistical method, the Al-13 clusters in the PACl coagulant and the Al-13 clusters formed by AlCl3 coagulation were confirmed to be an efficient coagulant species. In the real-time tracking experiments, the reversible transformations among Al-m, Al-o, Al-13 and Al-ts clusters were instantly observed after the addition of the coagulant (i.e., during the coagulation process). In the subsequent process (i.e., the flocculation process), only floc aggregation occurred, and no obvious transformations among the four types of Al clusters were observed. The continuous aggregation and increase in floc were mainly attributed to particle coalescence with the Al clusters. The mineral-water interface was inferred to favor the transformation of Al-m and Al-o aggregates into Al-13 as well as the reverse reaction (e.g., the degradation of Al-13).