可溶性有机物对绿麦隆水溶解度和正辛醇/水分配系数的影响

土壤中的可溶性有机物(dissolved organic matter,DOM)其组分既具有亲水基团又具有疏水基团,而疏水基团易与有机化合物(如农药)形成一种不稳定的复合物,这种作用能明显的影响农药在土壤中的迁移和扩散。而正辛醇／水分配系数(n-octanol-water partition coefficient,Kow)是衡量有机化合物疏水性的重要依据。本实验选用广泛应用于麦田杂草     

堆肥过程不同分子量水溶性有机物电子转移能力的演变及影响因素

利用超滤技术、电化学方法和光谱技术, 以堆肥水溶性有机物的不同分子量(MW)组分为研究对象, 分析在堆肥过程中不同分子量水溶性有机物(DOM)的组成特征、结构演变和电子转移能力变化的影响因素.结果表明, 类蛋白物质主要存在于堆肥前期的DOM(MW<1 kDa)中, 随着堆肥的进行, 类蛋白物质不断降解, 类富里酸物质持续合成, 堆肥后期类蛋白物质被完全降解, 类富里酸物质成为DOM(MW<1 kDa)主要的荧光组分.类腐殖物质是DOM(MW=1～3 kDa)、DOM(MW=3～5 kDa)和DOM(MW>5 kDa)的主要荧光组分, 堆肥过程中类腐殖质物质在3种不同分子量组分的变化各不相同, 但是堆肥后期类腐殖质物质在3个不同分子量组分的含量均高于堆肥初期. 堆肥过程中DOM(MW<1 kDa)的电子供给能力(EDC)呈降低趋势, 而电子接受能力(EAC)呈升高趋势; DOM(MW>5 kDa)的EDC在堆肥过程中呈上升趋势, 而EAC则无明显的变化规律.DOM(MW=1～3 kDa)和DOM(MW=3～5 kDa)的EDC和EAC在整个堆肥过程无明显变化规律.不同分子量组分堆肥DOM 的EAC受控于堆肥过程木质素降解产物的含量, 而其EDC变化与荧光参数和紫外参数无明显关系.     

光催化氧化处理过程中渗滤液溶解性有机物组分的三维荧光光谱变化特征

采用三维荧光光谱分析技术研究了垃圾渗滤液DOM不同组分的光催化转化特征。结果表明,憎水性碱(HOB)、憎水中性(HON)、憎水性酸(HOA)、亲水性酸(HIA)、亲水性碱(HIB)和亲水中性(HIN)组分在光催化处理过程中荧光光谱发生显著变化,HIA组分相对稳定。各组分中代表类腐殖酸区域的荧光信号在处理过程中变化最大,处理60 h后,该区域荧光峰完全消失,说明类腐殖酸类物质能优先发生光催化降解。在72 h光催化处理液中,主要残留可见区富里酸、类色氨酸和类酪氨酸的荧光信号,其中代表类蛋白的类色氨酸和类酪氨酸类物质占主要部分,说明光催化氧化能将大分子的腐殖酸和富里酸降解为小分子的类蛋白物质。     

不同分子尺寸溶解性有机物的光解行为研究

研究了三个分子量区间(0.45μm~100kDa,100~5kDa和5kDa)的溶解性有机物(DOM)在不同光源辐照下的光解行为。溶解有机碳(DOC)和UV254的测试结果表明,光解可以有效地减少所有分子量区间的DOM总量,而且UVC光源的存在可以进一步促进DOM的降解。三维荧光光谱测定结合平行因子分析,识别出3个腐殖质类荧光组分(C1:UVA+UVC,C2:UVA+UVB,C3:UVC)。在光解过程中,较大分子腐殖质类(5kDa)的荧光强度相对较稳定,甚至增强;而小分子腐殖质类(5kDa)的荧光组分C1和C2具有显著的光解行为,UVC的存在可以促进两种荧光组分的光解。所有分子量区间的C3组分都发生了光生成现象。     

离子液体中有机物溶解度的QSPR模型分析

采用偏最小二乘(PLS)分析方法对84个有机物在四种不同的离子液体中的溶解度进行基于VolSurf参数的定量构性关系(QSPR)研究,取得较好的结果.训练集模型对预测集具有良好的预测能力.参数分析表明有机物具有较大体积的亲水区域,对溶解度有利,且有机物与离子液体之间的相互作用能约为-0.84kJ·mol-1.一定的疏水性对溶解度也是有利因素,当离子液体具有小体积的疏水取代基,有机物具有不对称的局部疏水区域对溶解度有利,当离子液体具有大体积或多个疏水取代基,有机物较高的疏水体积对溶解度有利.多元线性回归(MLR)显示亲水参数W1最重要,表明分子的亲水性是影响有机物在离子液体中溶解的关键因素.     

堆肥中亲水性有机物还原容量表征及影响因素研究

还原容量(RC)是衡量水溶性有机物(DOM)还原特性的重要指标。分别取未腐熟和腐熟后筛分的堆肥样品提取DOM并分离亲水性组分(Hy I)作为电子供体及电子穿梭体,以3种不同形态的铁作电子受体测定其还原容量。结果表明,对于3种形态的电子受体Fe2(SO4)3,Fe(NO3)3和柠檬酸铁(FeCit),腐熟筛分后Hy I的还原容量值分别为15.88,13.41和51.45 mmol e-/mol C,均大于未腐熟阶段的Hy I还原容量值13.45,11.77和43.16 mmol e-/mol C。同时还发现不同电子受体对Hy I的还原能力影响明显,FeCit条件下测得的RC值明显高于在Fe2(SO4)3和Fe(NO3)3条件下的RC值。而且Hy I的微生物还原容量低于本底还原容量。通过紫外-可见光谱特征值(包括SUVA254和SUVA280)、特征值比值(包括A250/A365和A465/A665)及面积积分比值分析发现,芳香族、不饱和共轭双键结构、芳化度和有机质分子量都会对Hy I氧化还原能力产生影响;结合三维荧光光谱体积积分值及百分比分析发现,类腐殖质(包括类富里酸和类胡敏酸)相对含量是Hy I还原容量主要影响因素。本研究为科学表征亲水性组分的氧化还原特性、揭示其在堆肥体系污染物降解转化中的作用提供了科学依据。     

臭氧化对水厂水中消毒副产物生成势的影响

以某饮用水厂沿程工艺出水为研究对象,研究了臭氧化预处理对水体中消毒副产物(DBPs)氯化生成势的影响。结果表明,水厂生物处理单元产生的胞外聚合物(EPS)和溶解性微生物产物(SMP)等生物源有机物是非常有效的DBPs前体物,但其更易于氯化生成三卤甲烷(THMs)而非卤乙酸(HAAs)。水厂水中存在的THMs前体物主要是各类大分子量有机物,并且臭氧工艺对其有较好的氧化去除效果。水厂水中经臭氧氧化产生的小分子量有机物可能是更为有效的一氯乙酸(MCAA)和一溴乙酸(MBAA)前体物。此外,当水体中三氯乙酸(TCAA)前体物浓度较高时,臭氧工艺对TCAA生成势具有很好的去除效果。     

HPSEC-UV-ICP-MS法测定天然水体中元素在不同分子量段DOM中的分布

溶解有机物(DOM)对痕量金属的形态、生物可利用性及其最终归属都有着很大的影响. 由于腐殖质(HS)是DOM的最大组成部分, 占溶解有机碳比重的40％-70％, 而HS是由芳香族、酚族、 醌族和杂环的结构单元无规则缩合连接成的大分子. 这种多官能团的结构使得HS与痕量金属有着很强的络合能力, 从而增加了天然水体中的金属浓度. 本文利用此技术首次获得了11种元素在海水水体中DOM上不同分子量的天然分布, 探讨了DOM对痕量金属在天然水体中的形态及迁移的影响.     

臭氧氧化水中黄腐酸过程中有机物的形态变化

以黄腐酸为模型化合物,研究了臭氧氧化过程中有机物形态和结构的转化。采用超滤膜分级、GC／MS、电位滴定等手段考察了氧化中间产物的分子量分布、小分子有机物种类以及极性官能团的变化规律。结果表明,随着臭氧氧化反应的进行,有机物平均分子量显著降低;单位质量有机物（以DOC计）中极性官能团（羧基、酚羟基等）（mol／kg C）含量增加;同时伴随有十六酸、苯甲酸、十八醇等极性物质和丁二酸二（2-甲基丙）酯、直链烷烃等弱极性物质的生成。根据氧化过程中检测到的羟基自由基,提出黄腐酸的降解主要源于臭氧分子和羟基自由基的共同氧化作用;这两种具有不同反应机理的氧化剂对有机物的形态、结构与性质变化均有重要影响。     

吸附法处理水体中溶解性有机物的研究进展

综述了溶解性有机物(DOM)的性质、危害以及各种吸附剂在DOM去除中的研究现状.总结和介绍了吸附法处理DOM的主要机理和作用孔径,并对树脂吸附法处理DOM的研究提出了一些建议和展望.     

Effect of chlorination and ozone pre-oxidation on the photobacteria acute toxicity for dissolved organic matter from sewage treatment plants

The effect of chlorination and ozone pre-oxidation on the photobacteria acute toxicity for dissolved organic matter (DOM) from sewage treatment plants was investigated in this study. The results show that ozone pre-oxidation enhanced the photobacteria acute toxicity of the water samples. DOM before and after ozone pre-oxidation was fractionated by resins into six kinds of hydrophobic and hydrophilic organics. The six fractions were chlorinated individually and the photobacteria acute toxicity before and after chlorination was tested. It was found that the percentage of hydrophilic organics in DOM significantly increased after ozone pre-oxidation and hydrophilic organics exhibited remarkably higher acute toxicity than hydrophobic organics. In view of potentiometric titration and fourier transform infrared (FTIR) analysis, the hydrophilic organics showed a rather higher content of ph-OH structures than hydrophobic organics.     

Sonochemical reactions of dissolved organic matter

Property changes of Aldrich and Pahokee peat dissolved organic matter (DOM) at different ultrasonic frequencies and energy densities were systematically investigated. Exposure of DOM to ultrasound resulted in decreases in TOC, Color₄₆₅, specific UV absorbance (SUVA), aromaticity and molecular weight, while DOM acidity increased. Compared to 20 kHz ultrasound, greater sonochemical transformation of DOM occurred at 354 kHz and at higher energy density, due to greater ^·OH radical production. The changes to DOM properties suggest that ultrasound may significantly affect DOM-pollutant interactions (e.g.facilitate desorption of hydrophobic organics from DOM or promote complexation between metallic cations and DOM).     

Effect of solution chemistry on the fouling potential of dissolved organic matter in membrane bioreactor systems

Dissolved organic matter (DOM) as a potent foulant in membrane bioreactor (MBR) systems has attracted great attention in recent years. This paper attempts to elucidate the effect of solution chemistry (i.e. solution pH, ionic strength, and calcium concentration) on the fouling potential of DOM with different characteristics. Results of microfiltration experiments showed that the fouling potential of DOM having higher hydrophobic content increased more markedly at low pH due to the reduced ionization of carboxylic and phenolic functional groups of aquatic humic substances. In contrast, the fouling potential of hydrophilic DOM components and the molecular size of DOM appeared to be less affected by solution pH. The more compact molecular configuration of DOM at high ionic strength contributed to form a denser fouling layer, and limited the amount of foulants retained by the membranes on the other hand. DOM fouling potential greatly increased with increasing calcium concentration. The magnitude of the increase, however, was independent of the hydrophobicity of DOM, suggesting strong interactions exist between calcium ions and hydrophilic DOM components. Moreover, it was observed that the main mechanism governing the effect of calcium ions on the molecular size of DOM transited from charge shielding to complex formation as calcium concentration increased.     

Determinations of humic substances and other dissolved organic matter and their effects on the increase of COD in Lake Biwa.

Humic substances and other dissolved organic matter (DOM) in Lake Biwa and the surrounding rivers were investigated to elucidate their origins and behavior. An annual increase in chemical oxygen demand (COD) has been observed in the northern basin of Lake Biwa since 1985. The concentrations of dissolved organic carbon (DOC) in the northern and southern basins of Lake Biwa were 1.7-2.4 mgC/l and 1.9-2.6 mgC/l, respectively. The DOC concentrations tended to be high in summer and low in winter, and the seasonal changes in the concentrations of humic substances were small. The humic substances content of DOM was considered to be comparatively small because the ratio of the concentration of humic substances to DOC was in the range of 0.14-0.32. From the results of the fractionation of DOM in lake waters, it was estimated that hydrophobic acids, such as humic substances and hydrophilic acids, were about 25% and 45%, respectively. The main origin of hydrophobic acids in Lake Biwa may be humic substances from soils around the rivers that flow into Lake Biwa, while hydrophilic acids may be due to the inner production by phytoplankton. Therefore, the increase of COD in the northern basin of Lake Biwa may be attributed to the contributions of not only humic substances but also hydrophilic acids.     

Interactions of ozone with organic surface films in the presence of simulated sunlight: impact on wettability of aerosols

Heterogeneous reactions between organic films, taken as proxies for atmospheric aerosols, with ozone in presence of simulated sunlight and the photosensitizer 4-carboxybenzophenone (4-CB) were observed to alter surface properties as monitored by contact angle during the reaction. Attenuated total reflectance Fourier transform infrared spectroscopy (FTIR-ATR) was used in addition for product identification. Two types of model surfaces were systematically studied: 4-CB/4-phenoxyphenol and 4-CB/catechol. Solid organic films made of 4-CB/catechol were observed to become hydrophilic by simultaneous exposure to ozone and simulated sunlight, whereas organic films made of 4-CB/4-phenoxyphenol become hydrophobic under the same conditions. These changes in contact angle indicate that photo-induced aging processes involving ozone (such as oligomerisation) not necessarily favour increased hygroscopicity of organic aerosols in the atmosphere. The ratio between hydrophobic and hydrophilic functional groups should reflect the chemical property of organic films with respect to wettability phenomena. Contact angles and surface tensions of the exposed organic film made of 4-CB/4-phenoxyphenol were found to correspond to the hydrophobic/hydrophilic ratios obtained from the FTIR-ATR spectra.     

Three-dimensionally ordered macroporous cross-linked polystyrene incorporating functional group via hydrophilic spacer arm

<正>A versatile and effective method for incorporating functional groups on the pore wall of three-dimensionally ordered macroporous cross-linked polystyrene(3DOM CLPS) by hydrophilic spacer arm has been investigated.The 3DOM CLPS with pore size 865 nm was prepared by sacrifice template method.The hydrophilic spacer arm(polyethylene glycol,molecular weight is 600) was grafted to the 3DOM CLPS via nucleophilic substitution reaction.The other side of active hydroxyl can be further converted into a lot of other functional groups.In this report,the chelating ligand 2-mercaptobenzothiazole(MBZ) group was introduced on the end of the PGE chain to evidence the versatile functionalization approach.The functionalized ordered macroporous materials were characterized by FT-IR,element analyzer,SEM.The results reveal that the pores were successfully bonded with 2-mercaptobenzothiazole groups via hydrophilic spacer arms and the original morphology of ordered macroporous materials were remained after functionalization.The MBZ group density is 0.052 mmol/m~2.The functionalized 3DOM CLPS are expected to application as heavy metal ions adsorbent.     

Comparison of Green and Lowtran Radiation Schemes with a Discrete Ordinate Method UV Model

Abstract— Using the same input parameters for the calculations, the Green and Lowtran codes for calculating UV irradiances were compared to the discrete ordinate method (DOM) model by Stamnes et al , which was used as a reference. The comparisons were performed at 305 and 380 nm for different ozone concentrations, aerosol optical depths and aerosol absorption characteristics. No obvious dependencies on optical depth, single scattering albedo or column ozone were found for the ratio of the Green and the Lowtran code to the DOM model. At 380 nm the Green model agrees with DOM within 10%, whereas the Lowtran code shows discrepancies of ±25%. At 305 nm the Green model shows 10% higher values than the DOM model at low zenith angles and up to 80% lower values for zenith angles between 60 and 80°. The Lowtran code shows 60% higher values than DOM at small zenith angles and 60% lower values at large zenith angles. When the spectra from each model were weighted with the erythemal action spectrum the Green model overestimated the DOM results by less than 10% for zenith angles less than 50°. Discrepancies between DOM and Lowtran models exceeded 10% except for a small range of zenith angles.     

Membrane adsorption bioreactor (MABR) for treating slightly polluted surface water supplies: As compared to membrane bioreactor (MBR)

In this paper, a submerged membrane adsorption bioreactor (MABR) was evaluated for drinking water treatment at a hydraulic retention time (HRT) as short as 0.5 h. As powdered activated carbon (PAC) was added to the bioreactor at 8 mg/L raw water, the MABR achieved much higher removal efficiency for organic matter in the raw water than the parallel-operated membrane bioreactor (MBR). Moreover, the trans-membrane pressure (TMP) of MABR developed much lower than that of MBR, demonstrating PAC in MABR could mitigate membrane fouling. It was also identified here that the removal of dissolved organic matter (DOM) in MABR was accomplished through the combination of three unit effects: rejection by ultrafiltration (UF) membrane, biodegradation by microorganism, and adsorption by PAC; the last was of great importance. A sludge layer was observed on the membranes surface in both MABR and MBR and PAC particles themselves constituted a part of the cake layer and helped to intercept DOM in the mixed liquor by adsorption in MABR, especially for organic molecules of 5000–500 Da. The UF membrane together with the sludge layer and PAC layer in the MABR was able to reject hydrophobic bases (HoBs), hydrophobic neutrals, hydrophobic acids (HoAs), weakly hydrophobic acids (WHoAs) and hydrophilic matter (HiM) in the mixed liquor by 40.0%, 43.9%, 71.8%, 56.6% and 35.9%, respectively.     

Adsorption of the fusogenic peptide B18 onto solid surfaces: insights into the mechanism of peptide assembly

The adsorption and assembly of B18 peptide on various solid surfaces were studied by reflectometry techniques and atomic force microscopy. B18 is the minimal membrane binding and fusogenic motif of the sea urchin protein bindin, which mediates the fertilization process. Silicon substrates were modified to obtain hydrophilic charged surfaces (oxide layer and polyelectrolyte multilayers) and hydrophobic surfaces (octadecyltrichlorosilane). B18 does not adsorb on hydrophilic positively charged surfaces, which was attributed to electrostatic repulsion since the peptide is positively charged. In contrast, the peptide irreversibly adsorbs on negatively charged hydrophilic as well as on hydrophobic surfaces. B18 showed higher affinity for hydrophobic surfaces than for hydrophilic negatively charged surfaces, which must be due to the presence of hydrophobic side chains at both ends of the molecule. Atomic force microscopy provided the indication that lateral diffusion on the surface affects the adsorption process of B18 on hydrophobic surfaces. The adsorption of the peptide on negatively charged surfaces was characterized by the formation of globular clusters.     

Chemically modified resins for solid-phase extraction

The packings most widely used for solid-phase extraction are hydrophobic and make poor surface contact with aqueous samples unless the resins are first treated with an activating organic solvent such as methanol. Insertion of an acetyl- or hydroxymethyl group into a porous polystyrene-divinylbenzene resin provides a more hydrophilic surface that is easily wetted by water alone. Small columns of the chemically modified resins were found to be very efficient for the solid-phase extraction of many types of organic solutes from aqueous samples. Comparative recovery studies showed that the modified resins are superior to both silica packings and unmodified organic resins for the solid-phase extraction of organic compounds, and especially for polar organics such as phenols.