氢化物发生-原子荧光法同时测定污水中的砷和硒

用HNO3-HClO4消解液消解水样,断续流动进样,在KBH4-酸体系中,采用氢化物发生-原子荧光法同时测定污水中的砷和硒。在含浓盐酸2．0mL的介质中加入硫脲-抗坏血酸溶液5mL,在温度高于15℃时放置30min后,以15g/L KBH4溶液为还原剂,5％(体积分数)HCl为载流测定砷、硒荧光强度。在最佳实验条件下,砷、硒的相对标准偏差分别小于4％和2％,检出限分别为0．89μg／L和0．51μg／L,加标回收率分别为91．5％～101．2％和94．0％～100．5％。该方法精密度高、测定结果稳定,达到环境监测要求。     

土壤-植物系统中模拟酸雨与Cd复合污染的短期环境效应--黄豆盆栽试验

通过盆栽实验,研究了在黄豆(Glycne max)的一个生长周期内,模拟酸雨与Cd复合污染对土壤基本性质的影响,模拟酸雨作用下土壤-植物系统中Cd的迁移转化规律以及模拟酸雨与Cd复合污染对黄豆生长与生理特性的影响,探讨了土壤-植物系统中这种复合污染的短期环境效应.结果表明,短期内模拟酸雨和Cd污染对土壤-植物系统都有致害作用,但Cd污染的效应大于模拟酸雨的效应,模拟酸雨与Cd复合污染环境效应大于这2种污染物的单因素效应,且表现出明显的协同作用.在本试验条件下,pH值为3.5的模拟酸雨和20 mg·kg-1Cd的处理组合对土壤-植物系统的危害最严重.尽管在短期内,协同作用仅在土壤交换态Cd含量、黄豆茎和根中的Cd含量这3项指标上得到一定程度的体现,但这种复合污染的化学机制和环境效应值得关注,这2种污染物长时期共同作用对土壤-植物系统的影响也值得深入研究.     

不同碳源下的间歇曝气反硝化实验研究

本实验研究在序批式模式下高浓度硝酸盐的反硝化,比较用甲醇、醋酸钠和消化污泥上清液作碳源。实验发现,间歇曝气有助于提高反硝化污泥的沉降性能,而厌氧条件下,污泥的沉降性能差。污泥浓度4~5gVSS/L下,3种碳源都能有效地进行反硝化。最大硝酸盐去除率为0486gNO3N/gVSS·d。开始阶段,亚硝酸盐浓度增加,但用醋酸盐和硝化污泥上清液作碳源,其浓度最终下降为零。     

DSF-1菌产生的絮凝剂及处理洗煤废水的试验研究

对絮凝剂产生菌DSF 1的最适碳源、氮源进行探讨 ,考察了培养过程中培养液的粘度、絮凝活性的相互关系。提取、纯化所产絮凝剂 ,对其成分进行分析 ,并研究其在洗煤废水处理中的应用 ,同时初步探讨了该种絮凝剂的絮凝机理。结果表明 ,蔗糖与葡萄糖是DSF 1的理想碳源 ,而无机铵盐类则可作为其氮源 ;粘度和絮凝活性呈正相关性 ;DSF 1产生的絮凝剂活性成分可基本判定是阴离子型多糖 ,当用量为 0 5mL 5 0 0mg/L时 ,DSF 1产生的絮凝剂对pH =12 0、5 0mL 10g/L的模拟洗煤废水处理效果最好 ,低价 (+1,+2 )金属阳离子 (Ca2 + 、Mg2 + 、K+ 和Na+ )可以增强絮凝活性     

包裹块石煤固氟燃料制备工艺研究

以石灰或烧制白云岩与粘土、低氟无烟煤粉作为包裹材料,通过正交试验方法,对陕西省紫阳县蒿坪镇高氟块状石煤进行了固氟效果研究。结果表明,影响包裹石煤固氟效果的主要因素是无烟煤粉和石灰,影响顺序是无烟煤粉>石灰>粘土。最佳制备工艺条件为石煤块∶无烟煤粉∶石灰∶粘土=70∶10∶10∶5,固氟率达91.9%。     

初中环境案例教学的实践和研究

环境案例教学是通过对一个具体的环境教学情境的描述,引导学生对案例进行观察、调查、分析、讨论、实践、思考和归纳的一种开放式教学方法。这种方法,不仅有教会学生“知识”的方法,还包括教会学生“学习”的方法,从而培养创新意识和实践能力,是教法和学法的有机整合。环境案例教学的具体做法选编环境案例：这是实施环境案例教学的基础和前提。选编环境案例,一是学习环境案例的编写知识;二是根据学生的实际、适应时代的发展需要和《环境教育》（苏教版）教材;三是在正确的原则指导下,符合环境客观实际,精选案例。环境案例的类型：…     

Degradation of recalcitrant organic matter in SAARB leachate by a combined process of coagulation and catalytic ozonation

Environmental Science and Pollution Research - A combined coagulation and γ-Al2O3 catalytic ozonation process was used to treat semi-aerobic aged refuse biofilter (SAARB) effluent from...     

Ethylene,xylene, toluene and hexane are major contributors of atmospheric ozone in Hangzhou,China, prior to the 2022 Asian Games

Environmental Chemistry Letters - The occurrence of volatile organic compounds (VOCs) in the atmosphere is a major health issue, notably in China, because those compounds are the precursors of...     

Rapid and long-effective removal of broad-spectrum pollutants from aqueous system by ZVI/oxidants

• The coupling of oxidants with ZVI overcome the impedance of ZVI passive layer. • ZVI/oxidants system achieved fast and long-effective removal of contaminants. • Multiple mechanisms are involved in contaminants removal by ZVI/oxidant system. • ZVI/Oxidants did not change the reducing property of ORP in the fixed-bed system. Zero-valent iron (ZVI) technology has recently gained significant interest in the efficient sequestration of a wide variety of contaminants. However, surface passivation of ZVI because of its intrinsic passive layer would lead to the inferior reactivity of ZVI and its lower efficacy in contaminant removal. Therefore, to activate the ZVI surface cheaply, continuously, and efficiently is an important challenge that ZVI technology must overcome before its wide-scale application. To date, several physical and chemical approaches have been extensively applied to increase the reactivity of the ZVI surface toward the elimination of broad-spectrum pollutants. Nevertheless, these techniques have several limitations such as low efficacy, narrow working pH, eco-toxicity, and high installation cost. The objective of this mini-review paper is to identify the critical role of oxygen in determining the reactivity of ZVI toward contaminant removal. Subsequently, the effect of three typical oxidants (H₂O₂, KMnO₄, and NaClO) on broad-spectrum contaminants removal by ZVI has been documented and discussed. The reaction mechanism and sequestration efficacies of the ZVI/oxidant system were evaluated and reviewed. The technical basis of the ZVI/oxidant approach is based on the half-reaction of the cathodic reduction of the oxidants. The oxidants commonly used in the water treatment industry, i.e., NaClO, O₃, and H₂O₂, can be served as an ideal coupling electron receptor. With the combination of these oxidants, the surface corrosion of ZVI can be continuously driven. The ZVI/oxidants technology has been compared with other conventional technologies and conclusions have been drawn.     

Carbon nanotubes and Cu–Zn nanoparticles synthesis using hyperaccumulator plants

This article reports a novel way to synthesize carbon nanotubes and Cu/ZnO nanoparticles using metal hyperaccumulator plants. Metal hyperaccumulator plants are traditionally used for phytoremediation to clean soil polluted by toxic metals. However, the transfer of toxic metals in plant shoots and leaves is an environmental issue because animals and other living organisms feeding on plants will transfer the metals to the ecosystem. Therefore, we suggest that hyperaccumulator plants could be used to synthesize nanoparticles. Here, Brassica juncea L., a Cu-hyperaccumulator plant, was collected around a copper mine and used as a raw chemical to produce carbon nanotubes and Cu/ZnO nanoparticles. The chlorophyll in shoots of B. juncea plants was ethanol extracted to yield chlorophyllin. Cu and Zn were extracted by HNO₃ to form Cu/Zn(NO₃)₂. The chlorophyllin reacted with Cu/Zn(NO₃)₂ to form Cu/Zn chlorophyllin. Cu/ZnO nanoparticles were synthesized by direct precipitation of Cu/Zn chlorophyllin with NaOH and ethanol. The vascular bundles in B. juncea plants, which have been purified and carbonized by HNO₃, were rapidly heated to about 400°C and then they were cooled to room temperature to obtain carbon nanotubes. Results indicate that the outer diameter of carbon nanotubes was around 80 nm. Cu/ZnO nanoparticles have a Cu_0.05Zn_0.95O composition, and had a diameter of about 97 nm. Our study not only inspires the search for a new strategy on the synthesis of nanostructure from renewable natural products, but also breaks through the traditional and limited ideas about the reuse of metals by hyperaccumulator plants.