强化混凝去除黄浦江水有机物的试验研究

强化混凝去除有机物的效果与水源的分子量分布特性有着密切的关系.由于黄浦江水中低分子量的溶解性有机物占多数,因此,强化混凝处理有机物效果有限.对于＜1k分子量区间的有机物.增加混凝剂投量可有效去除紫外吸光值(UV254),但去除溶解性有机碳(DOC)的效果很差.尽管增加混凝剂投量和降低pH都能有效地去除有机物,但决定强化混凝效果的主要因素是pH,去除黄浦江水有机物的最佳pH范围为6～5.     

滕南煤田煤矸石对土壤的影响分析

通过对山东滕南煤田地区的土壤、煤矸石及部分农作物的灰份进行化学分析，从理论上探讨了其促进植物增产的机理；并认为该煤田3煤层的矸石含有与该地区土壤类似的化学组成，但其所含植物生长需要的主要元素普遍高于土壤中的含量，即煤矸石中含有较丰富的植物生长所需的矿物肥料。     

复杂粘性土层深基坑挡土桩受力分析

针对目前桩锚式支护计算方法的局限性，对复杂土层中下端固定的锚定式挡土桩作了受力分析，并编写了计算机程序，适用于处理深基坑支护中的分层土(砂土、粘性土)、有超载、存在地下水等各种复杂土层。     

新农药环境化学行为研究(V)-—三氟羧草醚(Acifluorfen)在土壤和水环境中的滞留、转化

从如下几方面研究了三氟羧草醚在土壤－水环境中的化学行为：一是土壤对该药的吸附，结果表明，吸附强度与土壤理化特性密切相关，Ｆｒｅｕｎｄｌｉｃｈ常数ｋｆ＝０．９４Ｗｏｍ＋０．６５Ｗｃｌａｙ－９．５９ｐＨ（ｒ＾２＝０．９４）；二是吸附机理研究，发现三氟羧草醚能与碱金属以外的许多金属离子形成配合物，并证实了与ＣＵ＾２＋形成的双核桥联合物的可能性；三是实验指出它在水中避光有一定的稳定性，不易水解；四是它在〈     

福建省海岸带土壤环境背景值研究及其应用

本文采用《福建省土壤环境背景值研究》课题的有关资料，研究福建省海岸带土壤主要元素背景值，讨论其主要影响因素，并应用来对福建省海岸带陆地土壤质量进行评价。     

大庆油田落地原油对土壤污染的研究

大庆油田是中国最重要的原油生产基地,开发建设50多年来,已累计生产原油18.2亿吨.不可避免地在油田生产过程中产生大量的落地原油,对土壤造成了严重的污染.落地原油在土壤中的迁移主要有横向迁移和纵向迁移:横向迁移对土壤的污染成辐射状分布,污染强度随污染源的距离增加而迅速降低,污染源周围污染最重的区域在0 m～40 m范围内,占总量90%以上,横向迁移范围确定在150 m以内;落地原油纵向迁移绝大部分集中在距土壤表面0 cm～10 cm范围内,竖向迁移一般不超过70 cm.落地原油污染土壤中主要污染物包括总烃、芳烃、酚、苯并[a]芘和硫化物,通过落地原油污染土壤的模拟实验可知总烃、芳烃、苯并[a]芘和硫化物含量,随原油浓度增加而明显增加,呈明显正相关性;其一元线性回归方程分别为Y=0.470X-17.88、Y=0.119X-6.13、Y=0.0076X-0.30、Y=0.000055X 0.089.     

典型北方高碱度微污染水体强化混凝的示范研究

以高碱度、受有机物污染的典型北方水体为例,探索适宜的强化混凝技术.在水质调查的基础上,提出适合水质特征的强化混凝目标.研究了高碱度水体强化混凝技术方法.研究表明,可以通过3条技术途径提高水体中有机物的去除效率.其一在混凝前优化pH,促进絮凝剂水解形成中聚体,AlCl3在pH 6左右,FeCl3在pH 5左右时,有机物去除率可以提高一倍左右;其二是强化沉淀软化;其三是絮凝剂优化.结合我国实际情况,通过对传统絮凝剂进行改性,研制出了适合我国北方水质特征的高效絮凝剂,能较传统絮凝剂将有机物去除率提高30%以上.     

影响土壤重金属生物毒性的若干因子

本文应用发光细菌法探讨了土壤类型、粘土矿物、无定形金属氧化物、吸附剂对重金属纯溶液以及重金属污染土壤的降毒效应.红壤、砖红壤对Cu、Cd、Pb呈现负的降毒效应,而对As具有明显的降毒作用.黑土、黄棕壤对供试阳离子金属具有明显的降毒效应,对As降毒却不明显.试验证明粘土矿物及其组成是影响土壤重金属毒性的最基本因素.无定形氧化锰对供试阳离子金属的降毒能力大于无定形氧化铁,对As的效应二者则相反.不同吸附剂对Cu、Cd、Pb呈现基本相同的降毒顺序,即炉烟灰>活性炭>泥炭>干活性污泥,不同配比吸附剂对红壤添加性阳离子和东乡铜矿污染土壤均具有明显的降毒作用.添加吸附剂的东乡铜矿污染土壤随着土壤溶液毒性的消除,随之也消除或减轻了其对水稻种芽的急性毒害.     

Simultaneous determination of dissolved organic nitrogen, nitrite, nitrate and ammonia using size exclusion chromatography coupled with nitrogen detector

Accurate quantification of dissolved organic nitrogen (DON) has been a challenge due to the cumulative analytical errors in the conventional method via subtracting dissolved inorganic nitrogen species (DIN) from total dissolved nitrogen (TDN). Size exclusion chromatography coupled with an organic nitrogen detector (SEC-OND) has been developed as a direct method for quantification and characterization of DON. However, the applications of SEC-OND method still subject to poor separations between DON and DIN species and unsatisfied N recoveries of macromolecules. In this study, we packed a series of SEC columns with different lengths and resin materials for separation of different N species and designed an independent vacuum ultraviolet (VUV) oxidation device for complete oxidation converting N species to nitrate. To guarantee sufficient N recoveries, the operation conditions were optimized as oxidation time ≥ 30 min, injection mass (sample concentration × injection volume) < 1000 µL × mg-N/L for macromolecular proteins, and neutral pH mobile eluent. The dissolved O₂ concentration in SEC mobile phase determined the upper limit of VUV oxidation at a specific oxidation time. Compared to conventional HW50S column (20 × 250 mm), HW40S column (20 × 350 mm) with mobile phase comprising of 1.5 g/L Na₂HPO₄·2H₂O + 2.5 g/L KH₂PO₄ (pH = 6.85) could achieve a better separation of DON, nitrite, nitrate, and ammonia. When applied to river water, lake water, wastewater effluent, groundwater, and landfill leachate, the SEC-OND method could quantify DON as well as DIN species accurately and conveniently even the DIN/TDN ratio reached 0.98.     

Insights into reactive oxygen species formation induced by water-soluble organic compounds and transition metals using spectroscopic method

Ambient particulate matter (PM) can cause adverse health effects via their ability to produce Reactive Oxygen Species (ROS). Water-Soluble Organic Compounds (WSOCs), a complex mixture of organic compounds which usually coexist with Transition Metals (TMs) in PM, have been found to contribute to ROS formation. However, the interaction between WSOCs and TMs and its effect on ROS generation are still unknown. In this study, we examined the ROS concentrations of V, Zn, Suwannee River Fulvic Acid (SRFA), Suwannee River Humic Acid (SRHA) and the mixtures of V/Zn and SRFA/SRHA by using a cell-free 2′,7′-Dichlorodihydrofluorescein (DCFH) assay. The results showed that V or Zn synergistically promoted ROS generated by SRFA, but had an antagonistic effect on ROS generated by SRHA. Fluorescence quenching experiments indicated that V and Zn were more prone to form stable complexes with aromatic humic acid-like component (C1) and fulvic acid-like component (C3) in SRFA and SRHA. Results suggested that the underlying mechanism involving the fulvic acid-like component in SRFA more tending to complex with TMs to facilitate ROS generation through π electron transfer. Our work showed that the complexing ability and complexing stability of atmospheric PM organics with metals could significantly affect ROS generation. It is recommended that the research deploying multiple analytical methods to quantify the impact of PM components on public health and environment is needed in the future.