School of Environmental Science and Engineering, Tianjin University, No. 92 Weijin Road, Nankai District, Tianjin 300072, China.
Academy of Environment and Ecology, Tianjin University, No. 92 Weijin Road, Nankai District, Tianjin 300072, China.
Environ Sci Technol. 2020 Sep 1;54(17):10916-10925. doi: 10.1021/acs.est.0c03233. Epub 2020 Aug 21.
Hydrogen peroxide (HO)-based electrochemical advanced oxidation processes (EAOPs) have been widely attempted for various wastewater treatments. So far, stability tests of EAOPs are rarely addressed and the decay mechanism is still unclear. Here, three HO-based EAOP systems (electro-Fenton, photoelectro-Fenton, and photo+ electro-generated HO) were built for phenol degradation. More than 97% phenol was removed in all three EAOPs in 1 h at 10 mA·cm. As a key component in EAOPs, the cathodic HO productivity is directly related to the performance of the system. We for the first time systematically investigated the decay mechanisms of the active cathode by operating the cathodes under multiple conditions over 200 h. Compared with the fresh cathode (HO yield of 312 ± 22 mg·L·h with a current efficiency of 84 ± 5% at 10 mA·cm), the performance of the cathode for HO synthesis alone decayed by only 17.8%, whereas the HO yields of cathodes operated in photoelectro-generated HO, electro-Fenton, and photoelectro-Fenton systems decayed by 60.0, 90.1, and 89.6%, respectively, with the synergistic effect of salt precipitation, OH erosion, organic contamination, and optional Fe contamination. The lower current decay of 16.1-32.3% in the electrochemical tests manifested that the cathodes did not lose activity severely. Therefore, the significant decrease of HO yield was because the active sites were altered to catalyze the four-electron oxygen reduction reaction, which was induced by the long-term erosion of OH. Our findings provided new insights into cathode performance decay, offering significant information for the improvement of cathodic longevity in the future.
基于过氧化氢(HO)的电化学高级氧化工艺(EAOPs)已广泛应用于各种废水处理。迄今为止,EAOPs 的稳定性测试很少涉及,其衰减机制仍不清楚。在这里,我们构建了三种基于 HO 的 EAOP 系统(电芬顿、光电芬顿和光电生成 HO)用于苯酚降解。在 10 mA·cm 的电流下,所有三种 EAOP 在 1 h 内可去除超过 97%的苯酚。作为 EAOPs 的关键组成部分,阴极 HO 生成率直接关系到系统的性能。我们首次通过在 200 小时以上的时间内在多种条件下操作阴极,系统地研究了活性阴极的衰减机制。与新鲜阴极(HO 生成率为 312±22 mg·L·h,电流效率为 84±5%,在 10 mA·cm 时)相比,单独用于 HO 合成的阴极性能仅衰减了 17.8%,而在光电生成 HO、电芬顿和光电芬顿系统中操作的阴极的 HO 生成率分别衰减了 60.0%、90.1%和 89.6%,这是盐沉淀、OH 侵蚀、有机污染和可选 Fe 污染的协同作用。电化学测试中电流衰减率较低(16.1%-32.3%)表明阴极并未严重失活。因此,HO 生成率的显著下降是因为活性位点发生了改变,从而催化了四电子氧气还原反应,这是由 OH 的长期侵蚀引起的。我们的发现为阴极性能衰减提供了新的见解,为未来阴极寿命的提高提供了重要信息。
