生物炭添加和灌溉对温室番茄地土壤反硝化损失的影响

生物炭添加和灌溉是番茄地常用的田间管理措施,然而其对反硝化的影响还不清楚.本研究种植试验设置3个灌溉量水平分别为估算作物生育期需水量ET0的50%(W50%)、75%(W75%)、100%(W100%)和3个生物炭添加水平分别为B0(折合纯碳,0)、B25(折合纯碳,25 t·hm-2)、B50(折合纯碳,50 t·hm-2),在2014年和2015年番茄收获后,每个试验小区采集具有代表性的土样进行室内培养试验,采用乙炔抑制法来研究土壤的反硝化损失和不加乙炔研究N_2O的排放量.结果表明生物炭和灌溉量显著改变了土壤的理化性质.与B0相比,添加生物炭能够提高土壤全碳、全氮含量和pH值,降低铵态氮、硝态氮含量,而灌水量降低了土壤中全氮和全碳的含量.因此,与B0/W50%相比,B25/W75%和B50/W100%处理显著减少了反硝化损失量(P0.05).生物炭和灌溉量的交互作用对土壤无机氮含量和反硝化损失的影响均达到显著水平(P0.05),且对硝态氮的影响表现为灌溉量生物炭添加量两者交互作用,对铵态氮的影响表现为生物炭添加量灌溉量两者交互作用,对反硝化损失的影响表现为灌溉量生物炭添加量两者交互作用.反硝化损失量与土壤中无机氮含量、(CO_2-C)矿化量与N_2O排放量均呈正相关关系.不同生物炭添加量和灌溉量处理后明显影响了N_2O/DN(P0.05),培养结束时,各处理下的N_2O累积排放量/DN累积排放量差异较大,介于0.31%~1.88%.     

菌株Desulfovibrio sp. CMX的DNRA性能和影响因素

微生物的硝酸盐异化还原为铵(DNRA)过程对自然界中铵根离子的存在和转化具有重要影响,然而关于SRB菌株DNRA过程影响和机制尚未探明.本文考察了实验室筛选的SRB菌株Desulfovibrio sp.CMX的DNRA能力、影响因素及其影响机制.结果表明,无外加氮源的情况下,分别以10 mmol·L-1NO_3~-和NO_2~-作为唯一电子受体,菌株Desulfovibrio sp.CMX最终NH_4~+生成率分别达到85.8%和97.3%,且无N2和N2O等副产物产生.实验探究了不同外加氮源、不同初始浓度的SO_4~(2-)、S~(2-)对菌株DNRA过程的影响.酵母浸粉作为外加氮源可促进菌株的生长和代谢从而促进菌株DNRA过程;SO_4~(2-)对于NO_3~-还原为NO_2~-阶段起促进作用,而对NO_2~-还原为NH_4~+阶段起抑制作用,综合两方面影响,最终表现出对菌株DNRA过程的抑制作用;S~(2-)对菌株生长及DNRA过程都表现出抑制作用,且S~(2-)浓度越高抑制作用越强,当S~(2-)浓度达到6 mmol·L-1后,S~(2-)对于NO_3~-还原为NO_2~-阶段的抑制作用强于NO_2~-还原为NH_4~+阶段的抑制作用,NO_3~-还原为NO_2~-速率低于NO_2~-还原为NH_4~+速率,此时体系中不再有NO_2~-的积累.     

苯酚对活性污泥活性及微型动物群落结构的影响

为了探究苯酚对污泥活性及微型动物群落结构的影响,以SBR工艺的活性污泥为研究对象,分析苯酚对污泥TTC-ETS活性、INT-ETS活性和微型动物群落结构及其动态变化的影响.结果表明,污泥TTC-ETS活性较之INT-ETS活性能够更有效表征有机毒害物质苯酚对污泥活性的影响,且随着进水苯酚浓度的增大,苯酚对污泥活性的抑制越明显:进水浓度在50mg·L-1时,苯酚对污泥活性的抑制率为(20.75±10.43)%.进水苯酚浓度为100 mg·L-1时,抑制率为(39.73±26.92)%,且波动较大.在300 mg·L-1进水运行后期,苯酚对污泥活性的抑制率稳定在40%左右;苯酚对活性污泥微型动物群落结构的影响随浓度的增大而增大,且对不同微型动物类群影响不同:在低浓度苯酚进水条件下,只有单个微型动物类群(有壳变形虫)受到明显的抑制,而当浓度增大至100 mg·L-1和300 mg·L-1时,对多个微型动物类群(固着型纤毛虫、有壳变形虫、匍匐型纤毛虫、肉食性纤毛虫等)产生抑制,对少数类群(鞭毛虫、线虫等)产生促进作用;苯酚影响下的污泥活性与微型动物之间存在一定的关联性,针棘匣壳虫(Centropyxis aculeata)、多变斜板虫(Plagiocampa mutabilis)等可作为含酚废水处理过程中污泥活性低的指示生物,湖累枝虫(Epistylis lacustris)、软波豆虫(Bodo lens)、跳侧滴虫(Pleuromonas jaculans)等可作为污泥活性高的指示生物.     

聚硅酸对不同形态铝沉积行为的影响

针对给水管网中残余铝沉积和再溶解现象可能引起的水质问题,研究了聚硅酸对不同水解聚合形态铝沉积、再溶解的影响,并以石英微晶天平为表征手段,初步探讨了聚硅酸对不同形态铝沉积、再溶解过程影响的机理.结果表明,聚硅酸能显著改变不同水解聚合形态铝的沉积、再溶解行为.聚硅酸可与3种水解聚合形态的铝迅速结合而生成可沉积产物,但产物性质不同.以单体形态为主的Al_0与聚硅酸的反应产物性质较稳定,部分以溶解态存在,部分以非溶解态(可沉积态)存在;尽管铝的两种聚合形态Al_(13)和Al_(30)与聚硅酸反应也生成了部分可沉积产物,但随着时间的推移,这些产物又逐渐向溶解态转化.铝硅比对Al_0体系中铝的沉积溶解行为影响较小,而对Al_(13)和Al_(30)影响较大,且在0.2∶20(以Al和SiO_2计的质量比)时,沉积态铝的溶解速率最快.     

2-丁烯醛生产废水中溶解性有机物的分级解析

采用超滤膜法将2-丁烯醛生产废水中的有机物分为相对分子质量不同的7个级分,并应用溶解性有机碳(dissolved organic carbon,DOC)、紫外吸收光谱(ultraviolet spectrum,UV)、傅里叶变换红外光谱(fourier transform infrared spectrometer,FT-IR)和气相色谱/质谱联用仪(gas chromatography with mass spectrometry,GC-MS)技术对不同相对分子质量区间的有机物所占比例及物质结构进行了研究.结果表明,废水中相对分子质量1×103的有机物所占比例最高,达到88.57%;采用GCMS对废水中相对分子质量1×103的级分进行分析,定性出27种化合物,包含醛、酮、酯、醇、酚、酸、烷烃类及其他苯系物等,其峰面积占有机物峰面积总和的比例分别为6.9%、5.3%、35.4%、13.2%、4.6%、0.4%、1.7%、16.8%,总和为84%.UV和FT-IR分析结果均显示不同相对分子质量区间的光谱吸收特征没有明显差别,级分中存在含有不饱和双键、羟基、羰基化合物及芳香族化合物,与GC-MS检测结果相吻合.研究结果为废水处理工艺的开发与优化提供了重要的指导作用.     

基于微生物生物完整性指数的地下水生态系统健康评价:以包钢稀土尾矿库周边地下水生态系统为例

生物完整性指数是水体生态系统健康评价的重要指标,已被广泛应用于湖泊河流等的生态系统健康评价中.但利用水体中分解者微生物群落构建IBI评价标准的报道很少,针对地下水生态系统的研究更是鲜见.本研究针对包钢稀土尾矿库周边地下水生态系统健康开展评价工作,基于地下水环境中微生物群落Illumina高通量测序信息,筛选关键环境因子,甄别敏感或耐受微生物分类属,确定候选生物参数,探索针对地下水的微生物完整性指数(microbiome index of biotic integrity,M-IBI)评价流程与标准构建方法.结果表明,总计12个地下水样点中,4个样点属于健康等级(Ⅰ级),占总样点的33.3%;2个样点属于亚健康等级(Ⅱ级),占总样点的16.7%;5个样点属于一般等级(Ⅲ级),占41.7%;1个样点属于较差等级(Ⅳ级),占8.3%;总体来看,靠近尾矿库的样点健康等级较低,而远离尾矿库参照点受到的干扰较小,健康等级较高,这可能与人类活动干扰影响程度密切相关.参照该地区地下水理化参数基础上的水质情况分析结果,发现应用M-IBI指数可较合理地评估包头稀土尾矿区周边地下水生态系统健康状况.结合生态系统健康内涵,本研究初步提出针对地下水生态系统健康的M-IBI指数评价体系构建流程.     

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.     

Evaluating the effectiveness of marine actinobacterial extract and its mediated titanium dioxide nanoparticles in the degradation of azo dyes

Aim of the present study was to synthesize titanium dioxide nanoparticles （YiO2 NPs） from marine actinobacteria and to develop an eco-friendly azo-dye degradation method. A total of five actinobacterial isolates were isolated from Chennai marine sediments, Tamilnadu, India and analyzed for the synthesis of TiO2 NPs using titanium hydroxide. Among these, the isolate PSV 3 showed positive results for the synthesis of TiO2 NPs, which was confirmed by UV analysis. Further characterization of the synthesized TiO2 NPs was done using XRD, AFM and FI＇-IR analysis. Actinobacterial crude extract and synthesized TiO2 NPs was found efficient in degrading azo dye such as Acid Red 79 （AR-79） and Acid Red 80 （AR-80）. Degradation percentage was found to be 81% for AR-79, 83% for AR-80 using actinobacterial crude extract and 84% for AR-79, 85% for AR-80 using TiO2 NPs. Immobilized actinobacterial ceils showed 88% for AR-79 and 81% for AR- 80, dye degrading capacity. Degraded components were characterized by FT-IR and GC-MS analysis. The phytotoxicity test with 500 μg/mL of untreated dye showed remarkable phenotypic as well as cellular damage to Tagetes erecta plant. Comparatively no such damage was observed on plants by degraded dye components. In biotoxicity assay, treated dyes showed less toxic effect as compared to the untreated dyes.     

Reaction mechanism and metal ion transformation in photocatalytic ozonation of phenol and oxalic acid with Ag+/TiO2

Photocatalytic ozonation of phenol and oxalic acid （OA） was conducted with a Ag^＋/TiO2 catalyst and different pathways were found for the degradation of different compounds. Ag^＋ greatly promoted the photocatalytic degradation of contaminants due to its role as an electron scavenger. It also accelerated the removal rate of OA in ozonation and the simultaneous process for its complex reaction with oxalate. Phenol could be degraded both in direct ozonation and photolysis, but the TOC removal rates were much higher in the simultaneous processes due to the oxidation of hydroxyl radicals resulting from synergetic effects. The sequence of photo-illumination and ozone exposure in the combined process showed quite different effects in phenol degradation and TOC removal. The synergetic effects in different combined processes were found to be highly related to the properties of the target pollutants. The color change of the solution and TEM result confirmed that Ag＋ was easily reduced and deposited on the surface of Tit2 under photo-illumination, and dissolved again into solution in the presence of ozone. This simple cycle of enrichment and distribution of Ag^＋ can greatly benefit the design of advanced oxidation processes, in which the sequences of ozone and photo-illumination can be varied according to the needs for catalyst recycling and the different properties of pollutants.     

Primary neuronal-astrocytic co-culture platform for neurotoxicity assessment of di-(2-ethylhexyl) phthalate

Plastics such as polyvinyl chlorides （PVC） are widely used in many indoor constructed environments; however, their unbound chemicals, such as di-（2-ethylhexyl） phthalates （DEHP）, can leach into the surrounding environment. This study focused on DEHP＇s effect on the central nervous system by determining the precise DEHP content in mice brain tissue after exposure to the chemical, to evaluate the specific exposure range. Primary neuronal-astrocyte co-culture systems were used as in vitro models for chemical hazard identification of DEHP. Oxidative stress was hypothesized as a probable mechanism involved, and therefore the total reactive oxygen species （ROS） concentration was determined as a biomarker of oxidative stress. In addition, NeuriteTracer, a neurite tracing plugin with ImageJ, was used to develop an assay for neurotoxicity to provide quantitative measurements of neurological parameters, such as neuronal number, neuron count and neurite length, all of which could indicate neurotoxic effects. The results showed that with 1 nmol/L DEHP exposure, there was a significant increase in ROS concentrations, indicating that the neuronal-astrocyte cultures were injured due to exposure to DEHP. In response, astrocyte proliferation （gliosis） was initiated, serving as a mechanism to maintain a homeostatic environment for neurons and protect neurons from toxic chemicals. There is a need to assess the cumulative effects of DEHP in animals to evaluate the possible uotake and effects on the human neuronal system from exoosure to DEHP in the indoor environment.