土壤化学反硝化及N2O产生机理研究进展

传统观点认为土壤氮素转化要有微生物的参与,但越来越多的研究发现,非生物转化在一些特定条件下同样发挥着不可忽略的作用,该途径下N₂O产生量甚至超过生物学过程而占主导作用.作为一种重要的非生物土壤氮素转化方式,化学反硝化产生途径虽然已经被发现近一个世纪,但在现代生态学研究中通常因研究分散而往往被忽视.鉴于此,对土壤化学反硝化及N₂O产生机制、影响因素的研究进展进行总结,并对化学反硝化的不足和薄弱环节提出展望.结果表明:土壤化学反硝化及N₂O产生的机制主要包括高价氮还原和羟胺分解两种作用;影响土壤化学反硝化的因素主要包括pH、温度、反应底物浓度、有机质、固相界面及金属离子,如高pH、固相界面和Cu2+的存在均会促进化学反硝化过程;不同形态Fe直接参与化学反硝化生成N₂O的途径不同,主要包括Fe2+还原NO₂-和NO₃-,Fe3+氧化NH₂OH.然而,现有研究对于化学反硝化机理的边界划分等问题仍不明确,因此,建议强化羟胺在土壤化学反硝化途径中作用机理的基础性研究,以及多因素综合影响下化学反硝化强度和N₂O产生特征方面的应用性研究.      

远程氩等离子体对聚醚砜膜表面性能的改性

采用双悬浮探针和电子自旋共振法定量对远程氩等离子体进行诊断,确定了电子、离子浓度和自由基浓度的分布,以预测表面改性的最佳区;利用远程氩等离子体对聚醚砜（PES）超滤膜进行表面改性,通过接触角测量、扫描电子显微镜和X射线光电子能谱分析改性前后膜表面结构和性能的变化,最后利用牛血清蛋白分离实验分析改性前后膜的分离性能和抗污染性能变化.结果表明,氩等离子体中电子、离子浓度沿轴向距离逐渐降低,在30cm后接近于0,而40cm处自由基浓度仍维持在90%以上,为可能的最佳表面改性区;在该区对PES超滤膜改性后,引入含氧基团和含氮基团,膜表面（O+N）/C原子比从0.18增大到0.46,增强膜表面极性;在最佳处理条件下,膜表面接触角从67°减小到18°,使膜表面亲水性能增强,抑制了电子、离子对膜的刻蚀作用;通过牛血清蛋白实验测定改性后膜污染率由70.3%减小到64.7%,抗污染性能提高.     

Impact of biosolids, ZnO, ZnO/biosolids on bacterial community and enantioselective transformation of racemic–quizalofop–ethyl in agricultural soil

The effects of biosolids,ZnO,and ZnO/biosolids on soil microorganism and the environmental fate of coexisting racemic–quizalofop–ethyl(rac-QE) were investigated.Microbial biomass carbon in native soil,soil/biosolids decreased by 62% and 52% in the presence of ZnO(2‰,weight ratio).The soil bacterial community structure differed significantly among native soil,soil/biosolids,soil/ZnO,and soil/biosolids/ZnO based on a principal co-ordinate analysis(PCo A) of OTUs and one-way ANOVA test of bacterial genera.Chemical transformation caused by ZnO only contributed 4% and 3% of the overall transformation of R-quizalofop-ethyl(R-QE) and S-quizalofop-ethyl(S-QE) in soil/ZnO.The inhibition effect of ZnO on the initial transformation rate of R-QE(rR-QE) and S-QE(rR-QE) in soil only observed when enantiomer concentration was larger than 10 mg/kg.Biosolids embedded with ZnO(biosolids/ZnO) caused a 17%–42% and 22%–38% decrease of rR-QEand rS-QE,although rR-QEand rS-QEincreased by 0%–17% and 22%–58% by the addition of biosolids.The results also demonstrated that the effects of biosolids on agricultural soil microorganism and enantioselective transformation of chiral pesticide was altered by the embedded nanoparticles.     

Transformation and migration of phosphorus in excess sludge reduction pretreatment by alkaline ferrate oxidation combined with anaerobic digestion

Recently,more and more attention has been paid to the strong oxidation ability of newly prepared potassium ferrate(NAPF) in sludge reduction process,but less attention has been paid to the change of phosphorus in this process.The feasibility of phosphorus migration and transformation during excess sludge reduction pretre atment using NAPF pre-oxidation combined with anaerobic digestion was investigated.After 70 mg/g suspended solids NAPF pretreatment and 16 days anaerobic digestion,the solid-phase volatile suspended solids decreased by 44.2%,and much organic matter had been released into the liquid-phase and then degraded during digestion by indigenous microorganisms.As the sludge pre-oxidation process was performed,solid-phase organic phosphorus and chemically combined phosphorus also released into the liquid-phase as PO_4~(3-),peaking at 100 mg/L.During anaerobic digestion,the Fe~(3+)in the liquid-phase was gradually reduced to Fe~(2+),and then formed Fe~(2+)-PO_4~(3-) compound crystals and re-migrated to the solid-phase.The concentration of PO_4~(3-) decreased to 17.08± 1.1 mg/L in the liquid-phase after anaerobic digestion.Finally,the phosphorus in the Fe~(2+)-PO_4~(3-) compound accounts for 80% of the total phosphorus in the solid-phase.A large number of vivianite crystals in sludge were observed.Therefore,this technology not only effectively reduces sludge,but also increases the proportion of PO_4~(3-)in the sludge in the form of Vivianite.     

The effect of dissolved oxygen concentration on long-term stability of partial nitrification process

Dissolved oxygen (DO) concentration is regarded as one of the crucial factors to influence partial nitrification process. However, achieving and keeping stable partial nitrification under different DO concentrations were widely reported. The mechanism of DO concentration influencing partial nitrification is still unclear. Therefore, in this study two same sequencing batch reactors (SBRs) cultivated same seeding sludge were built up with real-time control strategy. Different DO concentrations were controlled in SBRs to explore the effect of DO concentration on the long-term stability of partial nitrification process at room temperature. It was discovered that ammonium oxidation rate (AOR) was inhibited when DO concentration decreased from 2.5 to 0.5 mg/L. The abundance of Nitrospira increased from 10^11.5 to 10^13.7 copies/g DNA, and its relative percentage increased from 0.056% to 3.2% during 190 operational cycles, causing partial nitrification gradually turning into complete nitrification process. However, when DO was 2.5 mg/L the abundance of Nitrospira was stable and AOB was always kept at 10^10.7 copies/g DNA. High AOR was maintained, and stable partial nitrification process was kept. Ammonia oxidizing bacteria (AOB) activity was significantly higher than nitrite oxidizing bacteria (NOB) activity at DO of 2.5 mg/L, which was crucial to maintain excellent nitrite accumulation performance.     

巴松措表层沉积物中腐殖酸与富里酸的特性

采用紫外吸收光谱和GC-MS扫描解析,对西藏东南部湖泊巴松措表层沉积物中的腐殖酸和富里酸特性进行研究.结果表明,巴松措表层沉积物中腐殖酸和富里酸的紫外吸光度在200~400nm间较400~800nm间明显增加,富里酸在270nm附近出现弱而钝的双肩吸收,表明其中存在芳香环结构.腐殖酸和富里酸在254nm处的吸光度普遍偏低,表明其中难降解有机物的含量较低.通过紫外吸收特征值（A₄₆₅/A₆₆₅）分析得出,巴松措表层沉积物腐殖酸和富里酸的腐殖化程度较低.在人类活动频繁的区域,腐殖酸和富里酸的腐殖化程度相对于其他区域较高.根据GC-MS扫描解析,匹配度较高物质的分子式为C₁₅H₂₄,分子量为204,其结构中都含有芳香环,且含有脂肪链、不饱和烃、甲基、亚甲基、异丙基、环丙烷、己烷和萘等结构,均属于芳香族化合物,与紫外吸收光谱的分析结果一致.匹配度较高的物质推断属于类色氨酸.     

成渝城市群碳排放空间关联结构演化及影响因素

本文基于社会网络分析法（SNA）以及二次分配程序（QAP）方法,利用成渝城市群2005~2016年面板数据,对成渝城市群碳排放空间关联性及影响因素进行研究.结果表明：①成渝城市群碳排放空间关联性显著,呈现出复杂的网络结构形态,样本期内,网络密度由0.16增长至0.68,关联关系数从38个增长为162个.②重庆、成都、绵阳和南充等城市位于网络的中心地位,发出了较多的关联关系,同时发挥着中介作用.③碳排放空间关联网络被划分成为5个层级,层级结构整体较为稳定,然而第一层级与第二层级存在较为严重的断层现象.④空间距离、人口数量差异以及经济水平差异是碳排放关联性的主要驱动因素.城市间空间距离越近、人口数量与经济水平差异越大,越容易产生碳排放关联关系.     

典型稻田土壤真菌群落结构及多样性对比

为了解中国主要稻作区内不同母质发育的稻田土壤真菌群落结构和多样性差异,本研究选取由砖红壤、红壤、盐碱土、黑土和紫色土发育而来的5种中国典型稻田土壤为研究对象,利用高通量测序技术对土壤真菌群落组成及多样性进行对比分析.结果表明：5种典型稻田土壤的含水量、pH值、盐度及容重差异显著（P<0.05）;从Chao1指数来看,稻田土壤真菌群落丰度红壤型 > 黑土型 > 砖红壤型 > 紫色土型 > 盐碱土型.从ACE指数来看,群落丰度黑土型 > 红壤型 > 砖红壤型 > 紫色土型 > 盐碱土型.Shannon指数和Simpson指数均表现为群落多样性黑土型 > 紫色土型 > 红壤型 > 砖红壤型 > 盐碱土型;5种典型稻田土壤真菌门水平相对丰度最高的均是子囊菌门（Ascomycota）;砖红壤型和红壤型稻田土壤的优势真菌属为翅孢壳属（Emericellopsis）,紫色土型稻田土壤的优势真菌属为翅孢壳属、枝鼻菌属（Cladorrhinum）和柄孢壳属（Zopfiella）,黑土型稻田土壤的优势真菌属为翅孢壳属和明梭孢属（Monographella）,盐碱土型稻田土壤的优势真菌属为瓶头霉属（Phialocephala）;石黄衣属（Xanthoria）、Cyberlindnera、青霉菌属（Penicillium）和Westerdykella的相对丰度与土壤pH值呈显著负相关（P<0.05）,Ceroophora的相对丰度与土壤含水量呈极显著负相关（P<0.01）;帚枝霉属（Sarocladium）的相对丰度与可溶性有机碳呈极显著正相关（P<0.01）.以上研究表明,稻田真菌的群落结构和多样性受稻田开垦前土壤类型的影响,真菌物种丰度和优势菌种类型对土壤理化性质变化的响应较为敏感.     

热水解污泥-香蕉秸秆改善厌氧消化性能实验

采用添加高有机质含量的香蕉秸秆协同厌氧以及高温高压热水解预处理的方法,可显著提高低有机质污泥甲烷产率和厌氧消化性能。生化甲烷潜力实验结果表明:经过预处理后的污泥、香蕉秸秆及其混合物厌氧消化最大累积甲烷产量分别为388,372,537 mL/gVS,甲烷提升产量及协同效应显著。在污泥、香蕉秸秆及其混合物各自的最佳预处理条件下,甲烷产量达到80%的时间(T80)分别为12,19,17 d;SCOD溶出值分别为预处理前的14.4,2.8,5.9倍;厌氧消化结束后,SCOD去除率分别为93.7%、89.8%、94.5%;VS去除率分别为48.4%、48.8%、59.2%;热水解预处理使液相中溶解性蛋白质和VFA、溶解性多糖的浓度增加明显,分别为预处理前的14.5,5.1,8.2倍,随后的厌氧消化阶段的去除率分别为94.4%、94.9%和95.2%,稍高于单独厌氧消化的有机质降解率。     

基于蒙特卡罗模拟的沈阳城市表层土壤中多环芳烃的健康风险评价

为研究沈阳城市表层土壤中多环芳烃(PAHs)污染特征,于2017年9月采集了沈阳城区74个表层土壤样品,检测了土壤中16种优控PAHs的含量,并利用基于蒙特卡罗模拟的概率风险评价模型定量评估了其健康风险。结果表明:沈阳城市表层土壤中PAHs含量为283~21821 μg/kg,平均值为2370 μg/kg;与国内外其他城市土壤污染状况相比,沈阳城市表层土壤中PAHs的污染较为严重。健康风险评价结果表明,沈阳城市表层土壤中PAHs对儿童和成人造成的总致癌和非致癌风险均处于可接受的水平;其中,苯并[a]芘是致癌风险的最主要贡献物质,芘、荧蒽和菲是非致癌风险的最主要贡献物质。