硫酸盐废水处理产电过程中的电子分流机制研究

为探讨废水中硫酸盐对微生物燃料电池（MFC）产电效能的影响,采用单室空气阴极MFC反应器处理模拟硫酸盐废水,并对硫酸盐的电子分流过程进行了监测。结果表明,在一定范围内,提高硫酸盐浓度能使MFC的稳定电压上升,电池持续时间延长,MFC输出功率增大。随着进水硫酸盐浓度提高,微生物产生的电子总量中,硫酸盐还原捕获的电子和通过外电路的电子所占的比例均下降,分别由12．54％和31．45％下降至7_32％和8．49％。研究表明,较低浓度硫酸盐能够提高MFC的电能输出功率,但由于硫酸盐的还原将消耗掉大量电子,进而降低MFC的库伦效率。     

Highly efficient reduction of aqueous Cr(VI) with novel ZnO/SnS nanocomposites through the piezoelectric effect

In this work, novel ZnO/SnS nanocomposites were successfully synthesized via a hydrothermal approach, which is developed for piezoelectric catalytic reduction of hexavalent chromium (Cr(VI)) in an aqueous solution. The constructed ZnO/SnS nanocomposites exhibited higher catalytic efficiency for Cr(VI) reduction under a mechanical force (e.g., ultrasonic vibration) compared to pristine ZnO and SnS. In particular, the ZnO/SnS (with 30 wt.% of SnS) heterojunctions revealed an optimal degradation activity among all the prepared samples, which completely removed the Cr(VI) (20 mg/L) solution within 35 min. Moreover, the piezoelectric catalytic activity of ZnO/SnS remained stable after four consecutive cycling experiments. The results of the morphology observations indicated that the SnS nanoparticles adhere to the surface of the ZnO nanorods. The improved piezoelectric catalytic performance of the ZnO/SnS heterojunctions can be attributed to the formation of an intimate interfacial between ZnO and SnS, which effectively inhibits the electron-hole recombination and speeds up the rate of charge transfer. The study reveals a new design of ZnO/SnS heterojunctions as a high-performance and eco-friendly piezoelectric catalyst and provides a promising strategy for addressing environmental problems and energy crises.     

Phase transformation of Cr(VI)-adsorbed ferrihydrite in the presence of Mn(II): Fate of Mn(II) and Cr(VI)

Ferrihydrite is an important sink for the toxic heavy metal ions, such as Cr(VI). As ferrihydrite is thermodynamically unstable and gradually transforms into hematite and goethite, the stability of Cr(VI)-adsorbed ferrihydrite is environmentally significant. This study investigated the phase transformation of Cr(VI)-adsorbed ferrihydrite at different pH in the presence of aqueous Mn(II), as well as the fate of Mn(II) and Cr(VI) in the transformation process of ferrihydrite. Among the ferrihydrite transformation products, hematite was dominant, and goethite was minor. The pre-adsorbed Cr(VI) inhibited the conversion of ferrihydrite to goethite at initial pH 3.0, whereas little amount of adsorbed Mn(II) favored the formation of goethite at initial pH 7.0. After the aging process, Cr species in solid phase existed primarily as Cr(III) in the presence of Mn(II) at initial pH 7.0 and 11.0. The aqueous Mn concentration was predominantly unchanged at initial pH 3.0, whereas the aqueous Mn(II) was adsorbed onto ferrihydrite or form Mn(OH)₂ precipitates at initial pH 7.0 and 11.0, promoting the immobilization of Cr(VI). Moreover, the oxidation of Mn(II) occurred at initial pH 7.0 and 11.0, forming Mn(III/IV) (hydr)oxides.     

吡啶环改性石墨相氮化碳光催化还原Cr(VI)的研究

以三聚氰胺和吡啶二羧酸为原料,通过水热合成有机大分子前驱体,设计了吡啶环改性的石墨相氮化碳(x% Py-CN).利用TEM、XRD、XPS、FT-IR、EIS等手段对所得x% Py-CN催化剂进行表征分析.以水中Cr (VI)为目标污染物,考察了x% Py-CN催化剂的光催化还原性能.结果表明,在模拟太阳光照射下,10% Py-CN具有最佳的光催化性能,光照3h对15mg/L Cr (VI)光催化还原率达85%.x% Py-CN催化剂光催化活性提升的原因在于,吡啶环的修饰有效提高了光生电子空穴对的分离效率.此外,重复循环实验表明该催化剂具有良好的稳定性和循环利用能力,具有良好的应用前景.     

Enhanced remediation of Cr（Ⅵ）-contaminated groundwater by coupling electrokinetics with ZVI/Fe3O4/AC-based permeable reactive barrier

Although widely used in permeation reaction barrier（PRB） for strengthening the removal of various heavy metals, zero-valent iron（ZVI） is limited by various inherent drawbacks, such as easy passivation and poor electron transfer. As a solution, a synergistic system with PRB and electrokinetics（PRB-EK） was established and applied for the efficient removal of Cr（Ⅵ）-contaminated groundwater. As the filling material of PRB, ZVI/Fe₃O₄/activated carbon（ZVI/Fe₃O₄     

GB/T 28001-2011新版标准核心要素的理解

GB/T 28000《职业健康安全管理体系》系列标准于2012年开始正式实施,新版标准中对术语、定义和核心要素内容进行了大量的修订,正确地理解和贯彻标准核心要素是应用标准进行企业职业健康安全管理的根本所在,对预防和降低风险,确保职业健康安全管理体系的有效运行有着十分重要的意义.为使组织满足新版标准要求,本文对GB/T 28001-2011《职业健康安全管理体系要求》中核心要素——4.3.1危险源辨识、风险评价和控制措施的确定在内容上进行对比分析,并结合作者在实际工作中的案例和相关的法律法规和其他要求进行阐述,在此基础上对4.3.1要素进行理解,可以使组织对新标准的掌握和应用达到事半功倍的效果.     

某输出缓冲器的失效分析

本文通过对某输出缓冲器在质量一致性检验中的ESD考核环节失效的情况进行分析,找到了产品测试系统的异常情况,通过此次分析,进一步发现该产品的ESD保护设计一直以来存在的问题。文中不仅给出了失效机理,同时提出了改进措施并加以验证。此次失效分析对于同类器件的ESD保护设计,提高其可靠性具有一定的借鉴意义。     

SBBR工艺反硝化过程中N_2O和NO的产生情况

利用序批式生物膜反应器(SBBR),以葡萄糖为碳源(COD为500 mg/L),考察了不同碳氮比(COD与TN之比)、不同电子受体(NO_2~-或NO_3~-)、不同投加方式(碳源与氮源同步投加或投加碳源60 min后再投加氮源的异步投加)对N_2O产生情况的影响,以及碳氮比为2时NO的产生情况。实验结果表明:不论同步投加还是异步投加,两种电子受体的N_2O-N生成率均随着碳氮比的增大而下降;不同碳氮比下,投加NO2-时的N_2O-N生成率均高于投加NO3-时,异步投加时的N_2O-N生成率均大于同步投加时。说明低碳氮比、高浓度NO2-和胞内贮存物作碳源是反硝化过程中N_2O产生和大量积累的关键因素。此外,NO2-为电子受体时的NO-N生成率高于NO3-为电子受体时。     

Enhanced microbial reduction of aqueous hexavalent chromium by Shewanella oneidensis MR-1 with biochar as electron shuttle

Biochar, carbonaceous material produced from biomass pyrolysis, has been demonstrated to have electron transfer property(associated with redox active groups and multi condensed aromatic moiety), and to be also involved in biogeochemical redox reactions. In this study, the enhanced removal of Cr(VI) by Shewanella oneidensis MR-1(MR-1) in the presence of biochars with different pyrolysis temperatures(300 to 800 °C) was investigated to understand how biochar interacts with Cr(VI) reducing bacteria ...     

镍铁氧体@活性炭复合材料去除六价铬的表征、性能及机制

采用化学共沉淀法将镍铁氧体(NiFe₂O₄)负载到活性炭,制备出一种磁性吸附剂镍铁氧体@活性炭(NiFe₂O₄@AC),并将其用于吸附废水中的Cr(Ⅵ).研究了吸附剂吸附Cr(Ⅵ)的影响因素、吸附动力学和吸附等温线.结果表明,在温度为25℃、 pH为2、 Cr(Ⅵ)初始浓度为150 mg·L^-1、活性炭投加量为0.1 g、吸附时间为720 min时,NiFe₂O₄@AC吸附Cr(Ⅵ)的去除率达到96.92%,吸附量达到72.62 mg·g^-1.实验数据符合准二级动力学和Langmuir模型,表明其吸附过程是一个单层的化学吸附过程.热力学研究证实,温度升高有利于Cr(Ⅵ)在NiFe₂O₄@AC上的吸附,该吸附过程是自发和吸热反应.NiFe₂O₄@AC吸附机制主要是通过络合作用和静电吸引来吸附Cr(Ⅵ),同时,外加磁场可从溶液中分...