Remediation of arsenic contaminated soil by sulfidated zero-valent iron

• Sulfidation significantly enhanced As(V) immobilization in soil by zerovalent iron. • S-ZVI promoted the conversion of exchangeable As to less mobile Fe-Mn bound As. • Column test further confirmed the feasibility of sulfidated ZVI on As retention. • S-ZVI amendment and magnetic separation markedly reduced TCLP leachability of As. In this study, the influences of sulfidation on zero-valent iron (ZVI) performance toward As(V) immobilization in soil were systemically investigated. It was found that, compared to unamended ZVI, sulfidated ZVI (S-ZVI) is more favorable to immobilize As(V) in soil and promote the conversion of water soluble As to less mobile Fe-Mn bound As. Specifically, under the optimal S/Fe molar ratio of 0.05, almost all of the leached As could be sequestrated by>0.5 wt.% S-ZVI within 3 h. Although the presence of HA could decrease the desorption of As from soil, HA inhibited the reactivity of S-ZVI to a greater extent. Column experiments further proved the feasibility of applying S-ZVI on soil As(V) immobilization. More importantly, to achieve a good As retention performance, S-ZVI should be fully mixed with soil or located on the downstream side of As migration. The test simulating the flooding conditions in rice culture revealed there was also a good long-term stability of soil As(V) after S-ZVI remediation, where only 0.7% of As was desorbed after 30 days of incubation. Magnetic separation was employed to separate the immobilized As(V) from soil after S-ZVI amendment, where the separation efficiency was found to be dependent of the iron dosage, liquid to soil ratio, and reaction time. Toxicity characteristic leaching procedure (TCLP) tests revealed that the leachability of As from soil was significantly reduced after the S-ZVI amendment and magnetic separation treatment. All these findings provided some insights into the remediation of As(V)-polluted soil by ZVI.     

硫酸盐还原菌污泥固定化特性

采用玉米芯为碳源,聚乙烯醇(PVA)为包埋载体,饱和硼酸(H3BO3)为交联剂,研究了硫酸盐还原菌污泥(SRBS)、铁屑、麦饭石共固处理合成煤矿酸性废水的最优配比与机理,并分析了固定化过程中小球稳定性及活性的变化规律。实验结果表明,SRBS投加量是影响处理效果的最显著因子,当投加30%SRBS、2%铁屑、3%麦饭石时SO2-4、Mn2+去除率分别为94.13%和84.39%,溶液p H为7.03,未检测出Fe2+;随着交联时间的延长,小球膨胀率及SO2-4还原率分别呈线性与指数下降,从保持小球稳定性与活性角度考虑,可将交联时间设定为4~8 h;该法可为市政污泥的处置以及生物法处理煤矿酸性废水的工程应用提供技术参考。     

钙钛矿型La_(0.8)Ce_(0.2)Fe_(1-x)Co_xO_3催化剂的制备及其三效催化活性

采用自燃烧法制备了一组钙钛矿型复合氧化物La_(0.8)Ce_(0.2)Fe_(1-x)Co_xO_3(x=0.9,0.7,0.5,0.3,0.1),并考察了其对CO、C_3H_6和NO的三效催化活性。XRD和SEM表征结果显示,La_(0.8)Ce_(0.2)Fe_(1-x)Co_xO_3具有良好的钙钛矿型晶体结构,晶粒大小为纳米级并自组装成片状结构。催化剂的比表面积为14.73~22.43 m~2/g,含有微孔和介孔结构。催化活性评价结果表明:La_(0.8)Ce_(0.2)Fe_(0.1)Co_(0.9)O_3具有很好的三效催化活性,在理论空燃比的条件下,CO、C_3H_6和NO的起燃温度分别为195℃、264℃和290℃,完全转化温度分别为239℃、418℃和415℃,低温三效催化活性良好;Fe和Co的掺杂量同时影响着La_(0.8)Ce_(0.2)Fe_(1-x)Co_xO_3的催化效果。     

模糊综合评价法在钢铁企业安全投资合理性评价中的应用

为了对钢铁企业安全投资进行模糊综合评价,建立了钢铁企业安全投资的评价体系,确定各因素的权重。得出模糊综合评价矩阵,可对各因素进行评价分析;得出某钢铁企业安全投资现状分数为83.9分,等级为较好,需着重加强安全培训、劳保品、工业卫生等人因素方面的投资;在环境方面的投资较合理。     

纳米铁氧化物吸附处理重金属废水的研究进展

概述了用于吸附重金属的主要纳米铁氧化物的种类及其吸附效果,介绍了常见的纳米铁氧化物制备方法及改性方法,讨论了影响纳米铁氧化物吸附重金属的主要因素,并对纳米铁氧化物在水环境保护领域中的研究方向提出了展望:如发展绿色、高效的纳米铁氧化物制备工艺,探讨纳米铁氧化物结构调控和表面功能化对其吸附性能的影响等。     

电絮凝去除废水中多种重金属影响因素研究

目的以铁作为电极,研究电絮凝法处理含多种重金属废水的影响因素及效果。方法通过控制pH、停留时间、电流密度、电导率、废水初始浓度等因素至不同水平,考察处理效果、能耗及极板消耗的变化。结果随着停留时间、pH值及电流密度的升高,处理效果越好,但升高至一定程度后,处理效果提升并不明显;电导率对处理效果影响并不显著,但过低的电导率会增加能耗;废水初始浓度越高,要达到处理目标所需的能耗及极板消耗均越高。结论当pH为8.5~9.0、进水电导率为1500~2000μs/cm、停留时间为3~4 min、废水初始质量浓度20 mg/L、电流密度为13.2~19.8 A/m2时,处理效果最理想,对总铜、总镍、总铅、总锌、总镉及总铬的去除率达到99%以上,且能耗与极板消耗均为最低,电絮凝法更适合于重金属废水的深度处理。     

光助纳米铁还原Cr(VI)的研究

采用液相还原法制备了纳米铁,并用X射线衍射仪(XRD)、扫描电镜(SEM)对其晶体结构、形貌特征进行了表征.以Cr(Ⅵ)为模拟污染物,中压汞灯作为光源,考察了不同投加量、不同pH值等条件下光照对纳米铁还原Cr(Ⅵ)的影响.结果表明:制备的纳米铁具有很高的反应活性,粒径约为7.6nm,呈球形,可在空气中自燃.在25℃、Cr(Ⅵ)浓度为20mg/L、pH=7±0.5,加入0.1g的纳米铁,光照60min后Cr(Ⅵ)的还原率达到62.3%,而无光照时Cr(Ⅵ)的还原率仅为27.6%,说明光照对Cr(Ⅵ)的还原具有明显的促进作用.当纳米铁投加量较大时,纳米铁对Cr(Ⅵ)的还原速率大于光照对其产生的影响.反应液pH值对Cr(Ⅵ)还原速率的影响较光照对其产生的影响显著.在紫外光的照射下,纳米铁中电荷可能在诱导下作受迫振荡,与吸附分子发生电荷传递是光照促进纳米铁还原Cr(Ⅵ)的主要原因.     

Debromination of decabromodiphenyl ether by organo-montmorillonite-supported nanoscale zero-valent iron：Preparation, characterization and influence factors

An organo-montmorillonite-supported nanoscale zero-valent iron material(M-NZVI) was synthesized to degrade decabromodiphenyl ether(BDE-209). The results showed that nanoscale zero-valent iron had good dispersion on organo-montmorillonite and was present as a core-shell structure with a particle size range of nanoscale iron between 30–90 nm, characterized by XRD, SEM, TEM, XRF, ICP-AES, and XPS. The results of the degradation of BDE-209 by M-NZVI showed that the efficiency of M-NZVI in removing BDE-209 was much higher than that of NZVI. The efficiency of M-NZVI in removing BDE-209 decreased as the pH and the initial dissolved oxygen content of the reaction solution increased, but increased as the proportion of water in the reaction solution increased.     

基于总物流分析的我国钢铁工业生态效率分析

近年来我国钢铁产量快速增长且钢铁工业规模庞大,因此有必要对我国钢铁工业的生态效率进行研究. 采用总物流分析方法对我国钢铁系统的总物流进行分析,得到了钢铁系统的总物流分析指标;对1995—2011年我国钢铁工业的生态效率(包括资源效率、能源效率、脱钩指数等)进行了分析. 结果表明:2004年资源效率(粗钢产量与铁矿原矿消耗的比值)和资源经济效率(钢铁工业增加值与铁矿原矿消耗的比值)均达到最大值,二者分别为0.54 t/t和827.66元/t;2011年能源效率(粗钢产量与钢铁工业能耗的比值)和能源经济效率(钢铁工业增加值与钢铁工业能耗的比值)均达到最大值,分别为1.53 t/t和2 976.65元/t. 基于我国钢铁系统的总物流分析结果进行了脱钩指标分析,结果显示,DDEU(国内开采量的脱钩指数)为0.189,大于DMI(直接物质投入量)、TMR(总物质需求)及DPO(国内排放量)的脱钩指数(分别为0.115、0.084和0.061),即国内开采量的脱钩情况在该阶段达到最佳,这与我国铁矿石产量不足、钢铁生产更多依赖于进口资源密切相关. 最后提出了提高矿产资源综合利用率和重视废钢资源回收利用等相应的对策建议.     

填埋场中铁的生物化学循环对反硝化的影响

在模拟填埋体系中,以填埋场稳定的垃圾为接种物,通过控制有机物和硝氮负荷,研究了铁的生物化学循环对反硝化的影响.结果表明,垃圾填埋场内蕴藏着能实现铁的厌氧氧化还原并同步还原硝氮的复合功能菌群.通过改变有机物和硝氮的负荷,可使得填埋场内持续进行着铁的氧化还原循环和同步氮素转化.从氮素转化产物来看,铁的循环体系中氨氮浓度比传统的反硝化体系低4 mmol·L-1.填埋场内铁的生物化学循环过程对于原位脱氮具有极大贡献.