水相和冰相中不同pH条件下溶解性有机质对苊光降解的影响

以Suwannee River NOM（SRNOM）和Upper Mississippi River NOM（UMRNOM）两种水源溶解性有机质（DOM）为代表,利用500W高压氙灯作为光源模拟太阳光,进行室内光解实验.考察了冻融前后两种DOM在不同pH条件下的光谱特性参数及其与苊的结合常数（K_DOC）,同时通过苊的表观光解速率常数（K_OBS）研究冰相与水相中不同pH条件下DOM对苊的光解影响,并进行了相关性分析.结果表明,无论在冰相还是水相中,苊都可以直接进行光降解,同时两种DOM均能促进苊的光解.在水相中,随着pH的升高,两种DOM的SUVA₂₅₄、E₂/E₃、a₂₅₄、a₃₅₀与苊的K_OBS均有上升,而K_DOC则呈现下降趋势.同时K_OBS与K_DOC、a₃₅₀及SUVA₂₅₄均具有显著相关性.而冰相中,K_OBS和K_DOC随pH的变化趋势与水相一致,但SUVA₂₅₄、E₂/E₃、a₂₅₄、a₃₅₀没有明显变化趋势.K_OBS和K_DOC相比于水相也有明显下降.此外.冰相中的K_OBS仅与K_DOC存在显著相关,而与其他参数均无相关性,这也说明冰中的光化学反应可能具有更加复杂的机制.     

Photodegradation of chromophoric dissolved organic matters in the water of Lake Dianchi,China

Water samples were taken from Lake Dianchi, on the Yungui Plateau of southwest China, and experiments were conducted to simulate the photochemical degradation characteristic of chromophoric dissolved organic matter (CDOM) in the lake water. Three groups of experiments under different light conditions: ultraviolet (UV) light, visible light, and dark, were done and variations of fluorescence properties, UV absorbance, and dissolved organic carbon (DOC) concentrations during the experiments were analyzed to study the photodegradation process of CDOM with time. The result showed that light irradiation led to significant photochemical degradation of CDOM, resulting in changes in florescent properties, absorbance losses, decreases in aromaticity and average molecular weight, as well as decline in DOC concentration in the water. It was also observed that UV irradiation had greater effect than visible light did. However, various fluorophores had different sensitivities to the same irradiation condition, that is, protein-like fluorophore at the low excitation wavelengths is more sensitive to UV irradiation than the other fluorophores, and is more readily to undergo photo-degradation. In addition, visible light irradiation did not have significant impact on DOC in the water, with DOC concentration decrease by 5.57% –59.9% during the experiment time. These results may provide new knowledge on the environment behavior of CDOM in the water of Lake Dianchi.     

光照法处理垃圾渗滤液试验研究

采用直接光照处理青山垃圾填埋场和流芳垃圾填埋场的渗滤液,结果表明,直接光照处理4h,COD去除率分别为31%和18%,其主要原因在于青山垃圾填埋场中含有较多Fe和Cu等光催化物质及自身的光降解.直接光照对NH3-N和总-N的处理效果不佳.     

黄河水体颗粒物对3种多环芳烃光化学降解的影响

研究了、苯并(a)芘、苯并(ghi)3种多环芳烃在黄河水体中的光化学降解规律,探讨了黄河泥沙和黄土2种颗粒物对多环芳烃光化学降解的影响.结果表明:①当水体不含任何颗粒物时,多环芳烃的光降解符合一级反应动力学规律,且反应动力学常数随污染物初始浓度的降低而增加;3种多环芳烃的光降解速率与分子的吸收光谱相关.②黄土通过对光强的阻碍作用和其中所含腐殖质的光敏化作用影响多环芳烃的光化学降解,这2方面的共同作用导致不同浓度黄土所产生的影响不同.黄土浓度为0.1g/L或5g/L时促进了和苯并(a)芘的光降解;黄土浓度为5g/L时促进了苯并(ghi)的降解.当水体含有黄土时,多环芳烃的光降解符合二级动力学规律.③对多环芳烃光化学降解起主要作用的是黄土中存在的溶解性腐殖质,非溶解性腐殖质的作用不大.④由于黄河泥沙在河水中长期存在,泥沙中的溶解性腐殖质都已溶于水中,泥沙主要通过对光强的阻碍作用影响水体中多环芳烃的光降解,使光降解速率随泥沙浓度的增加呈幂指数降低.     

聚丙烯酰胺化学降解技术研究进展

聚丙烯酰胺化学降解技术是目前油田含聚污水处理的重要技术之一,包括氧化降解法、光降解法和光催化降解法。文章介绍了此项技术在降解机理和应用方面的研究进展,并通过实验证明了聚丙烯酰胺氧化降解和光降解的可行性,对油田污水中聚丙烯酰胺的化学降解处理具有一定的指导意义。     

水和正已烷中痕量四氯联苯光降解研究

多氯联苯(PC_Bs)已成为全球性污染物,在人类生存的各种环境因素中,包括空气、水体、土壤、生物体,甚至远离大陆的海洋中已都发现PC_Bs的存在.自从发现PC_Bs能吸收190—240nm和280—310nm紫外光以来,人们推断PC_Bs吸收阳光中的紫外线后的光降解可能是从环境中除去PC_Bs的一种有效途径.因此对PC_Bs的光降解.     

乙撑硫脲在土壤中光解的影响因素

研究了土壤湿度、温度和厚度对乙撑硫脲土壤光解的影响,并探讨了这一光解的深度和机制。实验结果表明,土壤湿度对乙撑硫脲光解有最显著的影响;光照下,总放射性在湿土中迅速向土表转移并集中于土表,而在干土中则不发生这种转移;乙撑硫脲在表土层以下2—5mm的土壤中也能发生光解。提出了乙撑硫脲的土壤中的光解,不是直接光解,而是需要O_2存在的间接光解的机制。     

溴氰菊酯在溶液中的光化学降解

在分别用λ>310nm和λ>295nm的紫外光照射下,溴氰菊酯在正己烷中都经历了三元环顺反异构化,α-碳旋光异构化及酯键断裂。λ>295nm时的光解速率是λ>310nm时的6.3倍,但异构化效率只有后者的78％。波长对异构化平衡组成及光解产物分布具有一定的影响。加入苯乙酮为光敏剂时,光解速率有明显的提高。去溴反应仅能在λ>295nm时发生,但苯乙酮的存在,则反应受到抑制。在λ>295nm时,溴氰菊酯在乙腈-水中的光解速率与在正己烷中的基本相同,但异构化的效率和平衡组成却有差异。在纯水中的光解速率远低于在上述两溶剂中的,但加入少量丙酮时,光解明显加快。不论有否丙酮存在,溴氰菊酯在纯水中均不发生异构化反应。鉴定了19个光解产物,并对光解反应的途径进行了讨论。     

纳米TiO2改性可见光催化降解有机物研究进展

光催化降解水中有机污染物是一项颇有发展前途的废水处理技术.目前主要的研究工作由紫外光逐步向可见光催化方向发展,使这项技术向实用性又迈进了一步.系统介绍了纳米TiO2的光催化降解有机污染物的原理,光催化处理水的现状,并从离子掺杂、表面光敏化和分子筛负载几个方面综述了可见光化的研究现状和发展方向.     

Photochemical degradation and mineralization of 4-chlorophenol

INTENTION, GOAL, SCOPE, BACKGROUND: Since the intermediate products of some compounds can be more toxic and/or refractory than the original compund itself, the development of innovative oxidation technologies which are capable of transforming such compounds into harmless end products, is gaining more importance every day. Advanced oxidation processes are one of these technologies. However, it is necessary to optimize the reaction conditions for these technologies in order to be cost-effective. OBJECTIVE: The main objectives of this study were to see if complete mineralization of 4-chlorophenol with AOPs was possible using low pressure mercury vapour lamps, to make a comparison of different AOPs, to observe the effect of the existence of other ions on degradation efficiency and to optimize reaction conditions. METHODS: In this study, photochemical advanced oxidation processes (AOPs) utilizing the combinations of UV, UV/H2O2 and UV/H2O2/Fe2+ (photo-Fenton process) were investigated in labscale experiments for the degradation and mineralization of 4-chlorophenol. Evaluations were based on the reduction of 4-chlorophenol and total organic carbon. The major parameters investigated were the initial 4-chlorophenol concentration, pH, hydrogen peroxide and iron doses and the effect of the presence of radical scavengers. RESULTS AND DISCUSSION: It was observed that the 4-chlorophenol degradation efficiency decreased with increasing concentration and was independent of the initial solution pH in the UV process. 4-chlorophenol oxidation efficiency for an initial concentration of 100 mgl(-1) was around 89% after 300 min of irradiation in the UV process and no mineralization was achieved. The efficiency increased to > 99% with the UV/H2O2 process in 60 min of irradiation, although mineralization efficiency was still around 75% after 300 min of reaction time. Although the H2O2/4-CP molar ratio was kept constant, increasing initial 4-chlorophenol concentration decreased the treatment efficiency. It was observed that basic pHs were favourable in the UV/H2O2 process. The results showed that the photo-Fenton process was the most effective treatment process under acidic conditions. Complete disappearance of 100 mgl(-1) of 4-chlorophenol was achieved in 2.5 min and almost complete mineralization (96%) was also possible after only 45 min of irradiation. The efficiency was negatively affected from H2O2 in the UV/H2O2 process and Fe2+ in the photo-Fenton process over a certain concentration. The highest negative effect was observed with solutions containing PO4 triple ions. Required reaction times for complete disappearance of 100 mgl(-1) 4-chlorophenol increased from 2.5 min for an ion-free solution to 30 min for solutions containing 100 mgl(-1) PO4 triple ion and from 45 min to more than 240 min for complete mineralization. The photodegradation of 4-chlorophenol was found to follow the first-order law. CONCLUSION: The results of this study showed that UV irradiation alone can degrade 4-CP, although at very slow rates, but cannot mineralize the compound. The addition of hydrogen peroxide to the system, the so-called UV/H2O2 process, significantly enhances the 4-CP degradation rate, but still requires relatively long reaction periods for complete mineralization. The photo-Fenton process, the combination of homogeneous systems of UV/H2O2/Fe2+ compounds, produces the highest photochemical elimination rate of 4-CP and complete mineralization is possible to achieve in quite shorter reaction periods when compared with the UV/H2O2 process. RECOMMENDATIONS AND OUTLOOK: It is more cost effective to use these processes for only purposes such as toxicity reduction, enhancement of biodegradability, decolorization and micropollutant removal. However the most important point is the optimization of the reaction conditions for the process of concern. In such a case, AOPs can be used in combination with a biological treatment systems as a pre- or post treatment unit providing the cheapest treatment option. The AOP applied, for instance, can be used for toxicity reduction and the biological unit for chemical oxygen demand (COD) removal.