Carena Luca, Vione Davide, Minella Marco, Canonica Silvio, Schönenberger Ursula
Dipartimento di Chimica, Università di Torino, Via Pietro Giuria 5, Torino 10125, Italy.
Dipartimento di Chimica, Università di Torino, Via Pietro Giuria 5, Torino 10125, Italy.
Water Res. 2022 Feb 1;209:117867. doi: 10.1016/j.watres.2021.117867. Epub 2021 Nov 15.
The carbonate radical CO and the excited triplet states of chromophoric dissolved organic matter play an important role in the photodegradation of some easily oxidized pollutants in surface waters, such as the aromatic amines. Anilines and sulfadiazine are known to undergo back-reduction processes when their degradation is mediated by the excited triplet states of photosensitizers (triplet sensitization). Back-reduction, which inhibits photodegradation, means that phenols or the antioxidant (mostly phenolic) moieties occurring in the natural dissolved organic matter of surface waters reduce, back to the parent compounds, the radical species derived from the mono-electronic oxidation of anilines and sulfadiazine. Here we show that a similar process takes place as well in the case of substrate oxidation by CO. The carbonate radical was here produced upon oxidation of HCO/CO by either HO, generated by nitrate photolysis, or SO, obtained by photolysis of persulfate. Back-reduction was observed in both cases in the presence of phenols, but at different extents as far as the details of reaction kinetics are concerned, and the occurrence of additional reductants might affect the efficacy by which phenols carry out the reduction process. In particular, when the carbonate radicals were produced by NO photolysis in the presence of HCO/CO, the numerical values of [PhOH] (the phenol concentration that halves the photodegradation rate of the substrate) were 2.19 ± 0.23 µM for aniline, 1.15 ± 0.25 µM for 3-chloroaniline, 1.18 ± 0.26 µM for 4-chloroaniline, and 1.18 ± 0.22 µM for 3,4-dichloroaniline. In contrast, when CO was produced by photolysis of persulfate in the presence of HCO/CO, the corresponding values were 0.28 ± 0.02 µM for aniline and 0.79 ± 0.10 µM for sulfadiazine. Back-reduction has the potential to significantly inhibit photodegradation by CO and excited triplet states in natural waters, and to comparatively increase the importance of HO-mediated degradation that is not affected by the same phenomenon.
碳酸根自由基CO以及发色溶解有机物的激发三线态在地表水中某些易氧化污染物(如芳香胺)的光降解过程中起着重要作用。已知苯胺和磺胺嘧啶在由光敏剂的激发三线态介导降解(三线态敏化)时会发生逆还原过程。逆还原会抑制光降解,这意味着地表水中天然溶解有机物中存在的酚类或抗氧化剂(大多为酚类)部分会将苯胺和磺胺嘧啶单电子氧化产生的自由基物种还原回母体化合物。在此我们表明,在底物被CO氧化的情况下也会发生类似过程。此处碳酸根自由基是通过硝酸盐光解产生的HO或过硫酸盐光解得到的SO对HCO/CO进行氧化而产生的。在两种情况下,当存在酚类时均观察到了逆还原现象,但就反应动力学细节而言程度不同,并且其他还原剂的存在可能会影响酚类进行还原过程的效率。特别是,当在HCO/CO存在下通过NO光解产生碳酸根自由基时,对于苯胺,[PhOH](使底物光降解速率减半的酚浓度)的数值为2.19±0.23μM,对于3-氯苯胺为1.15±0.25μM,对于4-氯苯胺为1.18±0.26μM,对于3,4-二氯苯胺为1.18±0.22μM。相比之下,当在HCO/CO存在下通过过硫酸盐光解产生CO时,苯胺的相应值为0.28±0.02μM,磺胺嘧啶为0.79±0.10μM。逆还原有可能显著抑制天然水体中CO和激发三线态介导的光降解,并相对增加不受同一现象影响的HO介导降解的重要性。
