中国医科大学附属第一医院综合废水处理及回用工程实践

中国医科大学附属第一医院 (简称中国医大一院 )建设综合污水处理及中水回用工程 ,提高了水的重复使用率 ,并将生产的中水回用至新病房大楼作为冲厕用水及院区景观绿化用水 ,在减少污水排放量的同时 ,取得了显著的环境效益和经济效益。     

煅烧结合光辐照提高纳米AgI/TiO_2的可见光响应

为提高AgI/TiO2的可见光响应能力,采用煅烧结合光辐照的工艺对其进行改性.紫外-可见光吸收分析表明,改性AgI/TiO2的敏感光谱范围覆盖了整个可见区,吸收边带从465nm红移至800nm,在500nm处的吸光度提高了近3倍.X-射线衍射分析结果指出,煅烧提高了金红石型TiO2的相对含量,导致禁带宽度从2.89eV降到2.81eV,氙灯辐照进一步增加了锐钛型TiO2、金红石型TiO2和AgI的相对含量,并生成了新的晶体AgCl,使其禁带宽度又降至1.55eV左右.AgCl的产生、AgI和金红石型TiO2相对含量的增加是降低改性材料禁带宽度和增强可见光响应能力的主要原因.研究还表明,只有煅烧后的AgI/TiO2才能通过光辐照来拓宽可见光敏感范围,而且,光辐照中起作用的主要是紫外光,可见光的作用甚小.研究最后提出将2种或2种以上的卤化银负载在纳米TiO2上,更能有效地增强TiO2的可见光响应能力.     

光催化氧化处理有机废水

介绍了光催化氧化法的原理,对光催化氧化法处理有机废水的可行性进行了试验,探讨了ＣＯＤ随反应时间的变化规律及催化剂用量,温度、浓度的影响。试验表明,光催化氧化可降解象洗涤剂这样难降解的有机物,反应１２０ｍｉｎＣＯＤ去除率可达５０％以上。     

地表水中石油类红外法与紫外法测定结果的比对

进行了红外光度法与紫外分光光度法测定混合油样、闽江干流水样和内河水样中石油类的比对试验 ,试验表明 ,两法所测结果相差较大 ,以红外法所得结果较符合水体实际情况 ,提出了红外光度法测定时的注意事项     

关于对水质分析中氨氮、总氮与总磷校准曲线的绘制与计算公式的探讨

本文从不同标液体积下的氨氮含量与校正吸光度、不同标液体积下的浓度与校正吸光度、不同标液体积下的校正吸光度与氨氮含量的一次函数关系中推导相关计算公式,让初学者灵活掌握与运用相关公式。     

双波长分光光度法测定含硝酸盐水样中二甲基乙酰胺

紫外分光光度法是目前水中N,N-二甲基乙酰胺(DMAC)的常用分析方法。研究结果表明,硝酸盐对紫外分光光度法测定DMAC具有很强的干扰。本研究中提出一种双波长法用于消除水中硝酸盐的干扰作用,所采用的波长对为194.0nm和219.0nm。精密度实验及加标回收实验表明,方法的相对标准偏差在4%以内,回收率为95%~102%,可有效消除硝酸盐的干扰作用。     

分光光度法测定废水中草甘膦的探讨

探讨了亚硝基衍生化紫外分光光度法测定废水中草甘膦的适用性,考察了硫酸加入体积对亚硝化反应的影响,提出应根据样品碱度调整硫酸用量。方法与高效液相色谱法测定值的重现性较好,应用于实际废水中草甘膦测定的加标回收率为95%～105%,平行测定的RSD≤1.3%,检出限为0.069 mg/L,检测上限为50.0 mg/L,废水中可能存在的伯胺和叔胺类物质对测定无明显干扰。     

Partial characterization,UV-induction and photoprotective function of sunscreen pigment,scytonemin from Rivularia sp. HKAR-4

Scytonemin, located in the extracellular polysaccharide sheath of some cyanobacterial species is considered an efficient natural photoprotectant against lethal doses of ultraviolet (UV) radiations. In the present study, scytonemin from the cyanobacterium Rivularia sp. HKAR-4 was partially characterized and investigated for its induction by UV radiation as well as its role in photoprotection. High-performance liquid chromatography (HPLC) with photodiode-array detection studies revealed the presence of an UV-absorbing compound with absorption maximum at 386 nm. Based on its absorption spectrum and ion trap liquid chromatography/mass spectrometry (LC/MS) analysis, the compound was confirmed as scytonemin. In comparison to photosynthetically active radiation, a significant induction in the synthesis of scytonemin was found under UV-stress. Scytonemin also exhibited efficient photoprotective ability by detoxifying the in vivo reactive oxygen species (ROS) generated by UV radiation and by reducing the formation of thymine dimers. To the best of our knowledge this is the first report on the UV-screening effects of scytonemin on in vivo ROS generation and thymine dimer formation in any cyanobacterial strain. Based on these findings, we conclude that scytonemin may play a vital role in the survival and sustainability of cyanobacterial life in adverse environmental conditions such as under high solar irradiances.     

Dimer formation during UV photolysis of diclofenac

Dimer formation was observed during ultraviolet (UV) photolysis of the anti-inflammatory drug diclofenac, and confirmed with mass spectrometry, NMR and fluorescence analysis. The dimers were combinations of the two parent molecules or of the parent and the product of photolysis, and had visible color. Radical formation during UV exposure and dissolved oxygen photosensitized reactions played a role in dimer formation. Singlet oxygen formed via photosensitization by photolysis products of diclofenac. It reacted with diclofenac to form an epoxide which is an intermediate in some dimer formation pathways. Quantum yield of photolysis for diclofenac was 0.21 ± 0.02 and 0.19 ± 0.02 for UV irradiation from medium pressure and low pressure mercury vapor lamps, respectively. Band pass filter experiments revealed that the quantum yield is constant at wavelengths >200 nm. The same dimers formed in laboratory grade water when either of the two UV sources was used. Dimers did not form in wastewater effluent matrix, and diclofenac epoxide molecules may have formed bonds with organic matter rather than each other Implications for the importance of dimer formation in NOM are discussed.     

Preparation, characterization, and photocatalytic activities of boron- and cerium-codoped TiO2

Boron- and cerium-codoped TiO2 photocatalysts were synthesized using modified sol-gel reaction process and characterized by X- ray diffraction （XRD）, X-ray photoelectron spectroscopy （XPS）, particle size distribution （PSD）, diffuse reflectance spectra （DRS）, and Brunauer-Emmett-Teller （BET）. The photocatalytic activities were evaluated by monitoring the degradation of dye Acid Red B （ARB）. The results showed that the prepared photocatalysts were mixed oxides mainly consisting of titania, ceria, and boron oxide. The structure of TiO2 could be transformed from amorphous to anatase and then to rutile by increasing calcination temperature; the transformation being accompanied by the growth of particle size without any obvious change in phase structure of CeO2. The XPS of B1.6Ce1.0-TiO2 prepared at 500℃ showed that a few boron atoms were incorporated into titania and ceria lattice, whereas others existed as B2O3. Cerium ions existed in two states, Ce^3＋ and Ce^4＋, and the atomic ratio of Ce^3＋/Ce^4＋ was 1.86. When boron and cerium were doped, the UV-Vis adsorption band wavelength showed an obvious shift toward the visible range （〈526 nm）. As the atomic ratio of Ce/Ti increased to 1.0, the absorbance edge wavelength increased to 481 nm. The absorbance edge wavelength decreased for higher cerium doping levels （Ce/Ti=2.0）. The particles size ranged from 122 to 255 nm with a domain at 168 nm （39.4%）. The degradation of ARB dye indicated that the photocatalytic activities of boron- and cerium-codoped TiO2 were much higher than those of P25 （a standard TiO2 powder）. The activities increased as the boron doping increased, whereas decreased when the Ce/Ti atomic ratio was greater than 0.5. The optimum atomic ratio of B/Ti and Ce/Ti was 1.6 and 0.5, respectively.