Abstract
Redox-active humic acids (HA) are ubiquitous in terrestrial and aquatic systems and are involved in numerous electron transfer reactions affecting biogeochemical processes and fates of pollutants in soil environments. Redox-active contaminants are trapped in soil micropores (<2 nm) that have limited access to microbes and HA. Therefore, the contaminants whose molecular structure and properties are not damaged accumulate in the soil micropores and become potential pollution sources. Electron transfer capacities (ETC) of HA reflecting redox activities of low molecular weight fraction (LMWF, <2.5) HA can be detected by an electrochemical method, which is related to redox potentials (Eh) in soil and aquatic environments. Nevertheless, electron accepting capacities (EAC) and electron donating capacities (EDC) of these LMWF HA at different Eh are still unknown. EDC and EAC of different molecular weight HA at different Eh were analyzed using electrochemical methods. EAC of LMWF at −0.59 V was 12 times higher than that at −0.49 V, while EAC increased to 2.6 times when the Eh decreased from −0.59 V to −0.69 V. Afterward, LMWF can act as a shuttle to stimulate microbial Fe(III) reduction processes in microbial reduction experiments. Additionally, EAC by electrochemical analysis at a range of −0.49–−0.59 V was comparable to total calculated ETC of different molecular weight fractions of HA by microbial reduction. Therefore, it is indicated that redox-active functional groups that can be reduced at Eh range of −0.49–−0.59 are available to microbial reduction. This finding contributes to a novel perspective in the protection and remediation of the groundwater environment in the biogeochemistry process.
Highlights
Humic acids (HA) as redox-active organic compounds can directly or indirectly affect the fates of pollutants in soil and water environments [1,2,3,4]
High-performance size-exclusion chromatography (HPSEC) is used in the past decades to isolate different molecular weights of HA [40], while we select the dialysis method to collect different molecular weight fractions of HA to better compare to the results of our previous studies
3500-Low molecular weight fraction (LMWF) of Leonardite humic acids Standard (LHA) and PPHA account for 2.0% and 3.6% of bulk HA, respectively, which were comparable to our previous study [10]
Summary
Humic acids (HA) as redox-active organic compounds can directly or indirectly affect the fates of pollutants in soil and water environments [1,2,3,4]. HA are supramolecular compounds of diverse self-assembled low molecular mass organic molecules, which form dynamic associations linked through hydrogen bridges and hydrophobic bonds [7,8,9]. Low molecular weight fraction (LMWF) of HA can be isolated by a new membrane dialysis method, and they can flow into soil micropores where many redox-active pollutants are trapped [10]. LMWF HA provides the possibility of bioremediation to treat active-redox contaminants in soil micropores. Redox activities of HA are associated with the number of redox-active functional groups (RAFGs) and redox potentials (Eh ). HA possess electron accepting capacities (EAC) and electron donating capacities (EDC) depending on the state of RAFGs [1,11,12]
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