污泥超高温堆肥过程中DOM结构的光谱分析

为了明确超高温堆肥新工艺在促进腐殖化进程中的优势,采用三维荧光光谱(3D-EEM)等光谱学方法研究了污泥超高温堆肥过程中DOM的结构特征及其变化规律.结果表明,堆体≥80℃的超高温阶段持续5 d(最高温度90℃),50℃以上高温阶段达到22 d,反映了堆肥过程中强烈的微生物代谢活性.E253/E203、SUVA280、S275~295等9个紫外-可见光光谱(UV-Vis)指标在0~23 d变化显著,指出DOM的芳香化和堆肥腐殖化程度逐渐增强.3D-EEM光谱结合荧光区域体积积分技术(FRI)分析指出,DOM中蛋白类物质在超高温堆肥过程的0~6 d几乎完全被降解;腐殖酸和富里酸类物质在0~23 d大量形成,堆肥在高温阶段达到完全腐熟,这与种子发芽指数(GI)在23 d所指示的腐熟度评价结果(98.5%)一致.基于多种光谱学指标的相关性分析,PⅤ,n/PⅢ,n与其它光谱学均呈现较好的相关性(r≥0.68),可以作为评价超高温堆肥腐熟度的光谱学指标.上述结果证实了超高温堆肥工艺可加快堆肥腐熟进程、缩短堆肥周期至20 d左右,在有机固废资源化领域具有极大的应用潜力.     

聚丙烯塑料-锯末干混合制备高介孔率柱状活性炭

以聚丙烯塑料和梧桐锯末为原材料,无水K2CO3为活化剂,采用干混合法制备高介孔率柱状活性炭.通过单因素实验,探究了塑料含量、盐料比、活化温度及活化时间对活性炭吸附亚甲基蓝(MB)性能的影响.结果表明:当塑料含量为20%、盐料比为2.5、活化温度为950℃、活化时间为80 min时,所制备的活性炭具有较高的MB吸附量(322.9 mg·g-1).所制备的活性炭具有发达的微观孔隙结构,其比表面积达到1461.99m2·g-1,平均孔径为3.23 nm,总孔容为1.04 cm3·g-1,其中,介孔孔容为0.80 cm3·g-1,介孔率超过70%,充分说明该方法可制备优质高介孔率柱状活性炭.     

高盐苯胺废水降解菌的筛选与特性分析

经富集、驯化分离筛选到的5株高盐苯胺降解菌对苯胺及实际废水均具有一定的降解能力。5株细菌的生长较为迅速,延迟期和平稳期均很短,生长最适温度为25℃,生长的最适pH接近中性。5株细菌对盐的耐受性可达18%,对实际废水的耐受性可达30%。其中3号菌株对苯胺的降解率最高,而22号菌株对实际废水的COD去除率最大。     

磷酸活化纺织固体废弃物制备活性炭及表征

以纺织固体废弃物为原料,磷酸为活化剂,采用一步活化法制备活性炭。采用正交实验研究了磷酸浓度、浸渍时间、活化温度和活化时间对活性炭吸附性能的影响,得到最佳工艺条件,借助氮吸附等温线、BET方程、BJH方程、SEM和FTIR分析了活性炭孔结构和表面化学性质。结果表明:最佳工艺条件为磷酸浓度40%(质量分数)、浸渍时间24h、活化温度500℃、活化时间30min。最佳条件下活性炭碘值为967mg/g,亚甲基蓝值为112mL/g,BET比表面积为1107.51m2/g,总孔容积为1.239cm3/g,中孔容积为1.024cm3/g,中孔占82.65%。活性炭表面具有羟基、羰基、内酯基和多种含磷官能团。     

Degradation of o-chloronitrobenzene as the sole carbon and nitrogen sources by Pseudomonas putida OCNB-1

A bacterial strain that utilized o-chloronitrobenzene(o-CNB) as the sole carbon,nitrogen and energy sources was isolated from an activated sludge collected from an industrial waste treatment plant. It was identified as Pseudomonas putida based on its morphology,physiological,and biochemical characteristics with an automatic biometrical system and the 16S rRNA sequence analysis. Microcosm study showed that the biodegradation of o-CNB was optimized at culture medium pH 8.0 and 32°C. At these conditions,the st...     

Organic matter extracted from activated sludge with ammonium hydroxide and its characterization

In order to characterize the organic properties of waste activated sludge in a wastewater treatment plant,organic matter within sludge was extracted with NH 3 ·H 2 O preferentially,and subsequently fractionated into five fractions using XAD-8/XAD-4 resins.Up to a 63.8%-71.1% of organic matter within the sludge could be efficiently extracted by NH 3 ·H 2 O.Fractionation results showed that hydrophobic acid and hydrophilic fraction were two main components among the sludge organic matter (accounting for 32.2% and 48.0% of the bulk organic matter,respectively),whereas transphilic acid,hydrophobic neutral and transphilic neutral were quite low (accounting for 9.2%,5.8% and 4.8%,respectively).Despite that the extractant of NH 3 ·H 2 O showed a relatively higher extraction efficiency of the aromatic components,the relatively low aromaticity of the organic fractions implied that those non-aromatic components could also be effectively extracted,especially for neutral and hydrophilic fractions.In addition,acidic fractions contained more aromatic humic-like components,whereas the neutral fractions had a greater content of aromatic proteins and soluble microbial byproduct-like components.Extraction of sludge organics with NH 3 ·H 2 O and subsequential fractionation using XAD resins could be a novel method for further characterization of sludge organics.     

Experimental investigation of adsorption capacity of anthill in the removal of heavy metals from aqueous solution

In the present work, the adsorption capacity of anthill was investigated as a low‐cost adsorbent to remove the heavy metal ions, lead (II) ion (Pb²⁺), and zinc (II) ion (Zn²⁺) from an aqueous solution. The equilibrium adsorption isotherms of the heavy metal ions were investigated under batch process. For the study we examined the effect of the solution's pH and the initial cations concentrations on the adsorption process under a fixed contact time and temperature. The anthill sample was characterized using a scanning electron microscope (SEM), X‐ray fluorescence (XRF), and Fourier transform infrared (FTIR) techniques. From the SEM analysis, structural change in the adsorbent was a result of heavy metals adsorption. Based on the XRF analysis, the main composition of the anthill sample was silica (SiO₂), alumina (Al₂O₃), and zirconia (ZrO₂). The change in the peaks of the spectra before and after adsorption indicated that there was active participation of surface functional groups during the adsorption process. The experimental data obtained were analyzed using 2‐ and 3‐parameter isotherm models. The isotherm data fitted very well to the 3‐parameter Radke–Prausnitz model. It was noted that Pb²⁺ and Zn²⁺ can be effectively removed from aqueous solution using anthill as an adsorbent.     

浸入式短流程超滤膜生产工艺过程膜污染的形成与控制

以江苏芦泾水厂膜技术改造工程为对象,从水质、膜工艺特征结合生产运行过程以及污染膜的清洗进行了分析,目的是了解膜污染的组分构成,评价不同清洗剂的清洗效果,获取较优的清洗顺序.结果表明,原水以憎水酸(HOA)和亲水组分(HIM)为主体,质量分数各占40.34%和28.48%.溶解性有机物(DOM)则以芳香性蛋白质Ⅱ类物质为...     

Optimizing synthesis conditions of nanoscale zero-valent iron (nZVI) through aqueous reactivity assessment

Nanoscale iron particles (nZVI) is one of the most important engineered nanomaterials applied to environmental pollution control and abatement. Although a multitude of synthesis approaches have been proposed, a facile method to screen the reactivity of candidate nZVI materials produced using different methods or under varying synthesis conditions has yet been established. In this study, four reaction parameters were adjusted in the preparation of borohydride-reduced nZVI. The reductive properties of the resultant nanoparticles were assayed independently using two model aqueous contaminants, Cu(II) and nitrate. The results confirm that the reductive reactivity of nZVI is most sensitive to the initial concentration of iron precursor, borohydride feed rate, and the loading ratio of borohydride to ferric ion during particle synthesis. Solution mixing speed, in contrast, carries a relative small weight on the reactivity of nZVI. The two probing reactions (i.e., Cu(II) and nitrate reduction) are able to generate consistent and quantitative inference about the mass-normalized surface activity of nZVI. However, the nitrate assay is valid in dilute aqueous solutions only (50 mg·L⁻¹ or lower) due to accelerated deactivation of iron surface at elevated nitrate concentrations. Additional insights including the structural and chemical makeup of nZVI can be garnered from Cu(II) reduction assessments. The reactivity assays investigated in this study can facilitate screening of candidate materials or optimization of nZVI production parameters, which complement some of the more sophisticated but less chemically specific material characterization methods used in the nZVI research.     

矿物超细颗粒的形成机制、结构特征及其环境行为和效应

矿物超细颗粒在自然环境中普遍存在,具有独特的环境行为和效应,对元素地球化学循环、污染物迁移转化和生态环境演变等有重要影响.矿物超细颗粒的环境行为和效应与其形成过程和结构特征密切相关.综述了物理、化学和生物过程驱动的矿物超细颗粒的形成机制,介绍了用于表征矿物超细颗粒结构特征的显微镜、光谱、质谱和同步辐射技术,分析了矿物超细颗粒在环境中的迁移转化及其与污染物的吸附、氧化还原和催化转化作用,总结了矿物超细颗粒的食物链积累、生物和生态毒性等环境效应,并对颗粒结晶路径、风险管控和微纳界面调控等重要研究方向进行了展望.超细颗粒是连接微观物质与宏观矿物晶体之间的桥梁,全面认识复杂基质中矿物颗粒的环境属性及其与污染物的微观作用机制,有助于指导矿物超细颗粒在环境污染修复中的应用,从而优化功能材料的设计,促进绿色低碳纳米技术的发展.