活性炭纤维负载TiO2催化剂的制备及其电催化性能

采用溶胶-凝胶法制备了活性炭纤维负载TiO₂催化剂（TiO₂/ACF）,并通过SEM和XRD等手段对TiO₂/ACF进行了表征。以邻苯二甲酸二甲酯（DMP）为目标降解物,考察了催化材料的电催化活性。实验结果表明：在反应温度为25 ℃、初始DMP质量浓度为100.0 mg/L、电解质Na₂SO₄质量浓度为100 mg/L、电流密度为62.5 mA/cm²、电极板间距为4 cm的条件下,经过40 min的降解,DMP质量浓度为1.8 mg/L,DMP去除率为98.2%;TiO₂/ACF在反应过程中可以原位再生,经6次重复使用后仍保持很高的催化活性,对DMP的去除率仍达90%以上。     

生态毒理基因组学——后基因组时代生态毒理学的新领域

基因组学、蛋白组学和代谢组学技术为生态毒理学的发展提供了生物高通量的技术手段,构成了新的交叉学科——生态毒理基因组学.生态毒理基因组学着重研究环境毒物暴露下非靶生物基因和蛋白的表达,能够在基因组水平上更深入地理解环境污染物的致毒机制,同时,它引进生物标志物为生态风险评价提供了平台.论文对生态毒理基因组学的发展历程、技术支持、模式生物及其在生态风险评价方面的应用进行了综述,以推动生态毒理基因组学技术在我国的进一步发展.     

Recycling thin film transistor liquid crystal display (TFT-LCD) waste glass produced as glass–ceramics

The waste electrical and electronic equipment (WEEE) directives are designed to deal with the rapidly increasing waste stream comprised of electrical and electronic equipment. Recycling electrical and electronic equipment reduces the quantity of waste going to final disposal. The demand for thin film transistor liquid crystal display (TFT-LCD) panels, commonly used in everyday electronic products, is increasing. Conventionally adopted treatments of TFT-LCD waste glass cannot meet WEEE directives. This study adopts the following operating conditions in fabricating glass–ceramics: sintering temperature of 800–950 °C; sintering time of 6 h; and, temperature increase rate of 5 °C/min. The glass–ceramic samples then underwent a series of tests, including the Vickers hardness, water absorption and porosity tests, to determine product quality. The Vickers hardness was 12.1 GPa when fired at 900 °C for 6 h, and density was 2.4 g/cm³ and water absorption was 0%. Thus, TFT-LCD waste glass can be regarded as a good glass–ceramic material.     

芳香类有机物氯化生成消毒副产物的特性研究

选择有代表性的芳香类有机物,在含有腐殖酸的水溶液中进行氯化试验.测定三卤甲烷和卤乙酸的生成特性.并分析有机物的化学结构对生成消毒副产物的影响.结果表明.各受试物氯化生成消毒副产物的活性和反应速率排序为间苯二酚>对苯二酚>邻苯二酚>苯酚>苯胺>苯甲酸>硝基苯;芳香类有机物苯环上官能团的性质、数量和位置等影响消毒副产物的生成;间苯二酚的氯化反应可分为快速反应阶段和慢速反应阶段.     

Investigation of the positive artifact formation during sampling semi-volatile aerosol using wet denuders

Wet denuders are used in several steam-based semi-continuous aerosol monitors to avoid gaseous absorption artifacts and pre-humidify the air stream, while simultaneously allowing measurements of water-soluble gaseous species. Unlike dry denuders, wet denuders saturate the sample air stream with water vapor, which can lead to re-partitioning of water-soluble volatile species to the aerosol phase, thereby causing a positive artifact in aerosol measurements. This paper investigates the magnitude of the positive artifact formation occurring in wet denuders using modeling techniques. Gaseous nitric acid was used as an example of volatile water-soluble gas in both flat and annular wet denuders. We have also verified the occurrence of the positive artifact in a flat wet denuder through a laboratory experiment. The model results indicate that the magnitude of the artifact is rather limited under typical conditions being less than 2.5% of ambient nitric acid concentration for the flat denuder and less than 0.6% for the annular denuder. The magnitude of the artifact increases with condensational sink of the aerosol (i.e. with the mean aerosol size and number concentration) and aerosol water solubility. While the artifact is relatively small in the absolute sense, it could be substantial for aerosol nitrate measurements, especially in ammonia limited conditions, when the concentration of the nitric acid is high and the concentration of nitrate is low. Therefore, we recommend that the artifact is assessed regularly by replacing the wet denuder with a dry denuder.     

不同装煤方式和炭化室高度的焦炉周边环境空气总悬浮颗粒物碳组分特征

研究了山西省4座典型焦炉周边环境空气中总悬浮颗粒物(TSP)碳组分特征,分析了不同装煤方式和炭化室高度对其的影响。结果表明:(1)焦炉周边环境空气中TSP质量浓度为711.95～2 938.41μg/m3,其中有机碳(OC)、元素碳(EC)的质量浓度分别为189.45～595.90、285.38～806.71μg/m3,总碳占TSP的质量分数为44.81%～67.45%;捣固焦炉周边的TSP及其碳组分浓度高于顶装焦炉,炭化室高度越高的焦炉周边环境空气中TSP及其碳组分浓度越低。(2)4座焦炉周边环境空气TSP中OC和EC质量比为0.66～1.04,说明焦炉周边环境空气中碳组分以一次污染为主。(3)4座焦炉周边环境空气TSP中碳组分的分歧系数为0.092～0.490,均小于0.5,总体来说装煤方式和炭化室高度都对焦炉周边环境空气TSP中碳组分的分布有一定影响,特别是装煤方式和炭化室高度都不同的焦炉周边环境空气TSP中碳组分差异较大。     

不同粒径垃圾焚烧底渣的特性和PAHs含量及毒性浸出

研究了不同粒径垃圾焚烧底渣的质量分布、物质成分(XRF)、晶体结构(XRD)、PAHs含量、酸反应特性、PAHs含量以及在2种浸出液中的毒性浸出情况。在比较国内外相关研究的基础上,实验得出垃圾焚烧底渣主要分布在粒径大于0.28 mm范围内,相比一些地区的研究结果要偏细;主要的物质成分为SiO2、CaO、Al2O3、Fe2O3、MgO、Na2O和K2O,而主要的晶体结构则分别为CaCO3、SiO2、Ca(OH)2和Mg0.3Ca0.97CO3,都与其他地区的研究结果基本相同;PAHs含量为0.043 4~0.247 mg/kg,与一些研究欧洲地区底渣中PAHs的含量的结果基本相近,且PAHs同类物的含量也随着底渣粒径的减小而增大;同时,实验还得出底渣中8种重金属在2种浸出液中的浸出浓度都未超出危险废物浸出毒性鉴别标准值(GB 5085.3-2007),但当底渣粒径大于0.6 mm时,其对环境中酸性物质的缓冲能力变弱。通过比较国外的一些研究结果,得出如将底渣作为建材利用时,需采用相应防范措施以防止其所含的重金属对周围土壤和水体的影响。希望能为进一步认识、处理和利用垃圾焚烧底渣提供一定的理论参考。     

钴铁镍三元水滑石催化PMS降解水中刚果红

采用化学共沉淀法制备由过渡金属钴、铁、镍组成的磁性三元水滑石CoFeNi-LDH,催化过硫酸氢钾（PMS）产生SO4-·自由基,降解水中偶氮染料刚果红（CR）,系统地考察了初始pH、催化剂投加量、PMS投加量对降解CR的影响。实验结果表明：在pH=4.0~10.0范围内,CoFeNi-LDH/PMS催化体系对CR的降解速率均较高;随着CoFeNi-LDH和PMS投加量的增加,CR的降解速率也逐渐加快。3次循环再生实验后,CoFeNi-LDH对CR的降解率在20 min内依然保持在88%左右。实验结果表明,这种新型磁性三元水滑石不仅具有高效的催化效果而且易于从水中分离,在有机染料废水的处理方面,有着良好的前景。     

Fe3O4/ZrO2-H2O2非均相类Fenton体系对3,4-二氯三氟甲苯的降解

以浸渍法制备的新型纳米Fe3O4/ZrO2为催化剂,3,4-二氯三氟甲苯(3,4-DCBTE)为目标污染物,用Fe3O4/ZrO2-H2O2非均相类Fenton体系对目标污染物进行降解,考察催化剂的催化效果和温度、pH、H2O2投加量和掺杂比等因素对催化剂催化效果的影响。结果表明,以纳米Fe3O4/ZrO2作为催化剂的非均相类Fenton体系对3,4-二氯三氟甲苯的处理效果极佳;随着温度的升高,纳米Fe3O4/ZrO2的催化效果不断提高;当pH降低时,催化剂的催化效果有明显提升,原始pH(pH=5.7)时反应去除效果最佳,去除率可达88.6%;催化剂用量的增加同样可以提高3,4-二氯三氟甲苯的降解效率;催化剂中Fe3O4:ZrO2的物质的量比为1:2时效果较其他掺杂比的催化剂效果更好,去除率最终可以达到96.82%;当H2O2投加量增加时,3,4-二氯三氟甲苯的降解效率先提高后降低,投加量为0.3 mL时去除效果最好,几乎可以完全去除目标有机物。以Fe3O4/ZrO2-H2O2非均相类Fenton体系处理3,4-二氯三氟甲苯时,目标污染物的降解符合一级反应动力学。     

生物酶生态修复重金属污染土壤

以多种重金属污染的土壤为材料,研究了酶对重金属的去除效果.在单因素实验基础上,采用响应面法对重金属去除的反应条件进行优化,结果表明,α-淀粉酶质量浓度0.2%、pH 3.5、反应时间12 h为最佳淋洗修复条件,Cd、Cr、Cu、Ni、Zn去除率分别为82.36%、75.02%、38.38%、34.69%和57.54%,去除率的大小顺序为Cd >Cr >Zn >Cu >Ni.酶作为土壤的组成部分,利用酶修复重金属污染的土壤,可以降低环境风险,具有较好应用前景.