Department of Civil and Environmental Engineering, The Hong Kong University of Science and Technology, Clear Water Bay, Kowloon, Hong Kong.
Department of Civil and Environmental Engineering, The Hong Kong University of Science and Technology, Clear Water Bay, Kowloon, Hong Kong; Hong Kong Branch of Chinese National Engineering Research Center for Control & Treatment of Heavy Metal Pollution, The Hong Kong University of Science and Technology, Clear Water Bay, Kowloon, Hong Kong.
Water Res. 2018 Oct 1;142:452-458. doi: 10.1016/j.watres.2018.06.018. Epub 2018 Jun 14.
UV-LEDs are considered as the most promising UV light sources, because it has the potential to replace conventional UV lamps in some water treatment applications in the foreseeable future. In this study, UV-LEDs at four wavelengths in the UV-C or near UV-C range (i.e., 257.7, 268, 282.3, and 301.2 nm) were used to investigate the wavelength-dependency on chlorine photolysis and its subsequent radical formation. The fluence-based photodecay rates of hypochlorous acid (HOCl) and hypochlorite (OCl) were monotonically correlated to their molar absorption coefficients and quantum yields, and the chlorine photodecay rates were much more significantly affected by molar absorption coefficients (β = 0.949) than quantum yields (β = 0.055). An empirical model that incorporated the chlorine photodecay rate constants, quantum yields, and molar absorption coefficients of HOCl and OCl was established, validated and then used to predict the chlorine photodecay rate at any wavelength (257.7-301.2 nm) and pH (5-10). The modelling results suggested that the maximum fluence-based rate constant (1.46 × 10 m J) was obtained at 289.7 nm and pH 9.95. The wavelength dependency was larger at alkaline pH than at acidic pH, and the pH dependency was the largest at the longest wavelength. The formation of hydroxyl radicals (HO·) and reactive chlorine species (RCS) decreased with increasing wavelength at pH 6, and increased with increasing wavelength at pH 7. More HO· was formed at pH 6 than pH 7, but RCS showed the opposite pH-dependency. The findings in this study provide the fundamental information in selecting UV-LEDs with specific wavelength for enhancing/optimizing chlorine photodecay and/or its radical generation at different pHs in real-world applications.
UV-LED 被认为是最有前途的紫外光源,因为它有可能在可预见的未来替代某些水处理应用中的传统紫外灯。在这项研究中,使用了四个在 UV-C 或近 UV-C 范围内的 UV-LED 波长(即 257.7、268、282.3 和 301.2nm)来研究波长对氯光解及其后续自由基形成的依赖性。次氯酸(HOCl)和次氯酸盐(OCl)的基于剂量的光降解率与它们的摩尔吸收系数和量子产率单调相关,而氯的光降解率受摩尔吸收系数(β=0.949)的影响远大于量子产率(β=0.055)。建立了一个包含 HOCl 和 OCl 的光降解速率常数、量子产率和摩尔吸收系数的经验模型,并对其进行了验证,然后用于预测任何波长(257.7-301.2nm)和 pH(5-10)下的氯光降解率。建模结果表明,在 289.7nm 和 pH 9.95 时获得了最大基于剂量的速率常数(1.46×10-3m2J)。在碱性 pH 下,波长依赖性比在酸性 pH 下更大,在最长波长下,pH 依赖性最大。在 pH 6 时,羟基自由基(HO·)和活性氯物种(RCS)的形成随波长的增加而减少,而在 pH 7 时则随波长的增加而增加。在 pH 6 时形成的 HO·比在 pH 7 时多,但 RCS 表现出相反的 pH 依赖性。本研究的结果为在实际应用中选择具有特定波长的 UV-LED 提供了基本信息,以增强/优化不同 pH 下的氯光解及其自由基生成。
