Reduction of Nitrate to Ammonium in Selected Paddy Soils of China

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Denitrification and Nitrate Reduction to Ammoniumin Taihu Lake and Yellow Sea Inter-Tidal MarineSediments

Denitrification and nitrate reduction to ammonium in Taihu Lake and Yellow Sea inter-tidal marinesediments were studied. The sediment samples were made into slurry containing 150 g dry matter per liter.Various amounts of glucose and 5 mmol L-1 of potassium nitrate were added in order to achieve differentratios of glucose-C to nitrate-N. Acetylene inhibition technique was applied to measure denitrification in theslumes. All samples were incubated anaerobically under argon atmosphere. Data showed that Taihu Lakesediment produced more N2O than marine sediment. Denitrification potential was higher in Taihu Lakesediment than in marne one. Glucose added increased denitrification activity but not the denitrification po-tential of the sediments. Dissimilatory nitrate reduction to ammonium seemed to occur in marine sediment,but not in freshwater one. When the marine sediment was treated with 25 mmol L-1 glucose, its denitrification poteatial, as indicated by maximum N2O production by acetylene blockage, was lower than that treatedwith no or 2.5 mmol L-l glucose. Acetylene was suspected to have inhibitory effect on dissimilatory nitratereduction to ammonium.

水体中DNRA与反硝化之间竞争研究进展

概述了DNRA过程的反应机制及相关DNRA菌的分类。讨论了关于影响DNRA效率的因素,包括氧化还原电位、溶解氧、碳氮比等。总结了各种因素对于DNRA过程与反硝化过程之间竞争的影响,介绍了两种测定DNRA过程的方法,综述了水体中DNRA过程及其相关影响因素,对于未来进一步深入研究DNRA过程,以及水体中氮元素的循环有着重要意义。

Marine aquaculture regulates dissimilatory nitrate reduction processes in a typical semi-enclosed bay of southeastern China

Marine aquaculture in semi-enclosed bays can significantly influence nutrient cycling in coastal ecosystems.However,the impact of marine aquaculture on the dynamics of dissimilatory nitrate reduction processes(DNRPs)and the fate of reactive nitrogen remain poorly understood.In this study,the rates of DNRPs and the abundances of related functional genes were investigated in aquaculture and non-aquaculture areas.The results showed that marine aquaculture significantly increased the denitrification(DNF)and dissimilatory nitrate reduction to ammonium(DNRA)rates and decreased the rate of anaerobic ammonium oxidation(ANA),as compared with non-aquaculture sites.DNF was the dominant pathway contributing to the total nitrate reduction,and its contribution to the total nitrate reduction significantly increased from 66.72%at non-aquaculture sites to 78.50%at aquaculture sites.Marine aquaculture can significantly affect the physicochemical characteristics of sediment and the abundances of related functional genes,leading to variations in the nitrate reduction rates.Although nitrate removal rates increased in the marine aquaculture area,ammonification rates and the nitrogen retention index in the aquaculture areas were 2.19 and 1.24 times,respectively,higher than those at non-aquaculture sites.Net reactive nitrogen retention exceeded nitrogen removal in the aquaculture area,and the retained reactive nitrogen could diffuse with the tidal current to the entire bay,thereby aggravating N pollution in the entire study area.These results show that marine aquaculture is the dominant source of nitrogen pollution in semi-enclosed bays.This study can provide insights into nitrogen pollution control in semi-enclosed bays with well-developed marine aquaculture.

硝态氮异化还原机制及其主导因素研究进展

硝态氮(NO_3^-)异化还原过程通常包含反硝化和异化还原为铵(DNRA)两个方面,是土壤氮素转化的重要途径,其强度大小直接影响着硝态氮的利用和环境效应(如淋溶和氮氧化物气体排放)。反硝化和DNRA过程在反应条件、产物和影响因素等方面常会呈现出协同与竞争的交互作用机制。综述了反硝化和DNRA过程的研究进展及其二者协同竞争的作用机理,并阐述了在NO_3^-、pH、有效C、氧化还原电位(Eh)等环境条件和土壤微生物对其发生强度和产物的影响,提出了今后应在产生机理、土壤环境因素、微生物学过程以及与其他氮素转化过程耦联作用等方面亟需深入研究,以期增进对氮素循环过程的认识以及为加强氮素管理利用提供依据。

氧化还原电位和pH对生物滞留系统硝酸盐异化还原为氨作用的影响

试验以模拟生物滞留系统为研究对象,运用^(15)N同位素示踪技术研究土壤不同氧化还原电位(Eh)和p H条件下硝酸盐异化还原为氨(DNRA)作用对氮的去除效果。结果表明:在土壤Eh为225~100 m V、0^-120 m V和-225^-340 m V条件下,随着Eh的降低,硝酸盐异化还原为氨(DNRA)作用增强;生物滞留系统中同时存在反硝化反应和DNRA作用,在0^-120 m V区间,更有利于反硝化作用的发生;在-225^-340 m V区间,更有利于DNRA作用的发生;生物滞留系统土壤p H为5~7的条件下,DNRA作用效果随着p H的增加而增强;在p H为7~9时,DNRA作用效果随着p H的增加而减弱;表明DNRA作用易在中性偏碱性的环境下发生。

碳源对微生物硝酸盐异化还原成铵过程的影响

微生物通过异化性硝酸盐还原成铵(DNRA)途径,硝态氮转化为仍可生物再利用的铵盐。以琥珀酸钠、柠檬酸钠、酒石酸钾钠为碳源,研究碳源的差异对有氧条件下微生物通过DNRA途径产铵的影响。结果显示,以琥珀酸钠和柠檬酸钠为碳源,初始浓度为20 mmol/L是较佳的实验条件,此时C/N约为1.5～2.0,NH4+-N质量浓度30.0～45.0 mg/L,最高产铵率分别为29.9%和27.0%;以酒石酸钾钠为碳源则在初始浓度为30 mmol/L,C/N约为2.0,NH4+-N质量浓度为40.0～45.0 mg/L时,最高产铵率为30.7%。反硝化和DNRA过程是同时存在的,培养液中NO3--N浓度的下降伴随着中间产物NO2--N的积累和NH4+-N浓度的升高。

养猪场处理尾水灌溉对太湖地区水稻土硝酸根异化还原为铵的影响

以太湖地区的普通简育水耕人为土(湖白土)和底潜简育水耕人为土(乌栅土)为研究对象,通过室内15N示踪实验研究了养猪场处理尾水灌溉对土壤硝酸根异化还原为铵(DNRA)的影响。底潜简育水耕人为土(乌栅土)DNRA速率和相对潜势分别为N 0.68～0.79 mg kg-1d-1(以干土计)和34.61%～44.45%;普通简育水耕人为土(湖白土)DNRA速率和相对潜势分别为N 1.14～1.41 mg kg-1d-1(以干土计)和54.24%～106.70%。养猪场处理尾水对2种土壤的DNRA速率均影响不大;养猪场处理尾水对普通简育水耕人为土(湖白土)DNRA相对潜势影响不大而明显降低了底潜简育水耕人为土(乌栅土)DNRA相对潜势。相关分析表明,土壤DNRA相对潜势与培养开始(r=0.836,p<0.05,n=6)和结束(r=0.936,p<0.01,n=6)时的土壤溶解有机碳/硝态氮(DOC/NO3--N)均显著正相关,而与培养始末土壤Eh和DOC含量的相关性不显著。以上研究结果表明,太湖地区底潜简育水耕人为土(乌栅土)具有较高的DNRA潜势,实践上有可能通过调控DN-RA过程实现保持土壤氮素而减少农田氮损失的目的;尾水灌溉主要通过改变土壤DOC/NO3--N而影响DN-RA对NO3-异化还原的贡献,且其影响因土壤类型而异。

活性污泥中硝酸盐异化还原为铵的影响因素研究

针对活性污泥系统中硝酸盐异化还原为铵(DNRA)导致系统脱氮效率降低的问题,通过长期驯化培养试验、批式试验和高通量测序,考察水力停留时间(HRT)、硫离子(S^(2-))的投加和流态对活性污泥中DNRA氨化的影响。研究结果表明:间歇流条件下,当HRT由6 h延长至36 h时,DNRA氨化随着HRT的延长而增强,系统中生成氨氮质量浓度由0.43 mg/L逐渐增长至15.98 mg/L;连续流条件下,当HRT由6 h延长至48 h时,系统中生成氨氮质量浓度由2.03 mg/L逐渐增长至20.78 mg/L。投加S^(2-)可有效促进硝酸盐氮转化成氨氮,当向系统投加20 mg/L的S^(2-)时,间歇流和连续流系统出水氨氮质量浓度分别增加了11.58%和24.82%。且连续流下投加S^(2-)后,DNRA功能菌总丰度比投加前提高了22.65%。在改变HRT和进水S^(2-)质量浓度时,连续流系统中硝酸盐氮转化成氨氮比例均普遍高于间歇流系统。

亚铁作用下湿地基质对水中氮素和COD去除效应研究

采用模拟试验法,以人工湿地基质为材料,添加不同浓度的硫酸亚铁,研究湿地基质对铵态氮和硝态氮的去除效应以及COD的去除效果。结果表明:亚铁添加强化了湿地基质对铵态氮的吸附能力和硝化作用,也减少了水中硝态氮的积累,促进氮素的去除,其中150mg/L的亚铁添加基质对总氮和铵态氮的去除效果最好,其48h去除率分别为29.24%和33.66%;而100mg/L的亚铁添加对硝态氮去除效果较好,其去除率可达37.16%,但是由于硝态氮异化还原成铵过程的存在,使总氮的去除效果下降。基质对铵态氮去除效应中COD的去除效果明显低于基质对硝态氮去除效应中COD的去除效果,这说明厌氧环境有利于COD的去除。本研究结果可为改进人工湿地去除污染物能力提供理论依据。

太湖潜流带有机质含量对硝酸盐还原途径的影响

通过太湖原状沉积物柱室内模拟试验,研究了有机质(腐殖酸)和硝态氮随下行水流进入潜流带对氮素转化和硝态氮还原途径的影响。结果表明,仅输入硝态氮时,潜流带中硝态氮出现持续累积现象,硝态氮还原速率为0.087-0.186μg/(cm^(3)·d)(平均0.162μg/(cm^(3)·d));而同时输入腐殖酸和硝态氮时,潜流带还原性环境逐渐增强,在21 d内Eh值降至-200 mV以下,硝态氮还原速率为0.092-0.251μg/(cm^(3)·d)(平均0.220μg/(cm^(3)·d)),腐殖酸有效促进了硝酸盐的还原。反硝化作用是潜流带中硝酸盐还原的主要途径,特别是潜流带上部(0-22.5 cm),其贡献达到90%以上;而潜流带的深部(22.5-45.0 cm)硝酸盐还原量总体较小,反硝化作用贡献也仅占39.5%。随着腐殖酸的消耗(6.92 mg/L降为3.32 mg/L),硝酸盐异化还原成铵过程对硝酸盐还原的贡献由14.0%降为2.7%。综合来看,补充有机质有利于潜流带特别是浅层潜流带的硝酸盐还原,且以反硝化过程为主,对湖泊水体碳氮循环和去除具有重要作用。

傀儡湖沉积物-水界面硝酸盐异养还原过程研究

反硝化(DNF)和硝酸盐异养还原为氨(DNRA)是水域生态系统中硝酸盐异养还原的2个主要过程.DNF和DNRA之间的竞争控制着硝酸盐在水域生态系统中的异养还原方式和最终归趋.选取太湖流域的傀儡湖为研究对象,采用室内培养实验和稳定氮同位素示踪技术,考察傀儡湖沉积物-水界面的DNF和DNRA速率及其对硝酸盐异养还原过程的贡献.结果显示,沉积物表现为NH_4^+-N的源和NO_3^--N的汇,潜在DNF速率为18.89~54.00μmol/(kg·h)[均值(36.39±3.86)μmol/(kg·h)],DNRA反应速率为1.02~5.89μmol/(kg·h)[均值(3.21±1.15)μmol/(kg·h)].DNF与沉积物有机质含量和含水率存在显著的正相关关系,DNRA与沉积物需氧量(SOD)之间存在相关性.反硝化是傀儡湖中硝酸盐异养还原的主导过程,贡献率为84.23%~96.90%,而DNRA过程只占3.10%~15.77%.与海洋河口区域相比,淡水湖泊生态系统中DNRA速率和DNRA在硝酸盐异养还原中所占的比重均较小.

碳源性质和COD/NO_3^--N对硝酸盐还原途径的影响

通过批次试验考察了实际工业有机废水的碳源性质和COD/NO_3^--N对硝酸盐还原途径的影响。研究结果表明,木薯酒糟中含有大量的大分子易发酵有机物(如碳水化合物和蛋白质等),更易发生异化硝酸盐还原为铵(DNRA)过程;而葡萄糖合成废水和木薯酒精废水厌氧出水中,硝酸盐还原途径主要是通过反硝化进行的。虽然基质不同,但COD/NO_3^--N对硝酸盐还原途径的影响却呈现出相同的规律,即随着COD/NO_3^--N增大,反硝化所占的比例逐渐减小,DNRA占的比重逐渐增大。

自组装膜进样质谱系统及其在砂质沉积物异化硝酸盐还原研究中的应用

沉积物中的异化硝酸盐还原过程对于海洋氮循环起着至关重要的作用。基于15N标记的培养技术是目前测定沉积物异化硝酸盐还原的主要手段。准确快速测定15N标记的产物(29N2、 30N2)是量化异化硝酸盐还原各个过程速率的关键。本研究自行组装膜进样质谱系统用于29N2和30N2的测定,对其测量条件进行了优化。结果表明,进样蠕动泵进样流速0.80 mL/min,进样时间3~3.5 min,恒温槽温度20~25℃,同时铜还原炉温度在300~600℃的条件下,^29N2/^28N2和^30N2/^28N2的测试精密度分别可以控制在0.1%和1%以内,比较适合29N2和30N2的测定。利用自组装的膜进样质谱系统结合15N标记的培养技术研究了青岛石老人沙滩沉积物中的异化硝酸盐还原过程。石老人沙滩沉积物不存在将硝酸盐完全还原为氮气好氧的反硝化。厌氧铵氧化、厌氧反硝化和异化硝酸盐还原为铵(Dissimilatory Nitrate Reduction to Ammonium,DNRA)的潜在速率(以湿沉积物N计)分别为(0.05±0.01) nmol/(cm^3·h),(2.32±0.21) nmol/(cm^3·h)和(1.02±0.15) nmol/(cm^3·h)。厌氧反硝化是硝酸盐异化还原主要的贡献者,其比例接近70%,其次是DNRA,比例可达30%,而厌氧铵氧化的贡献最低,仅为1%。在N2产生过程中,主要贡献者是反硝化,厌氧铵氧化的贡献仅为2%。

河岸带介质中硝态氮衰减机制的实验研究

通过采集河岸带沉积物开展微宇宙实验,探究了NO-3-N在河岸带沉积物中的衰减机制。结果表明:实验后水中NO-3-N浓度从100 mg/L衰减到了1 mg/L以下,河岸带介质对水体中NO-3-N有显著的去除作用,去除率高达99.7%;NO-3-N在河岸带介质中衰减的是同化合成有机氮、反硝化作用以及异化还原作用(DNRA)共同作用的结果;3种作用对NO-3-N衰减的贡献率分别为56.6%、26.6%和13.1%,少部分的NO-3-N(3.7%)被沉积物吸附。

基于次溴酸钠氧化-氨基磺酸还原测定沉积物^(15)N加富培养样品中的^(15)NH_(4)^(+)的方法探索

沉积物中的异化硝酸盐还原过程是海洋中活性氮转化的关键过程之一。不同于反硝化和厌氧铵氧化,异化硝酸盐还原为铵(DNRA)是将硝酸盐直接还原为铵,而不是以氮气的形态移除,这有可能会加重水体富营养化和缺氧。目前测定沉积物中异化硝酸盐还原过程的主要手段是^(15)N标记培养技术。为了准确评估DNRA的潜在速率,首先要准确测定加富样品中的^(15)N H_(4)^(+)浓度。常用测定^(15)N H_(4)^(+)的方法为基于次溴酸钠-碘氧化膜进样的四极杆质谱法。然而此方法的分析物之一^(30)N_(2)在分析时容易存在两个问题而导致结果失真:一是易受样品中O_(2)干扰而导致^(30)N_(2)含量被显著高估;二是^(30)N_(2)在检测器中平衡较慢从而导致测试时间较长且精密度较差。为解决上述问题,本研究采用次溴酸钠氧化-氨基磺酸还原的方法将^(15)N H_(4)^(+)转化为^(29)N_(2)后通过膜进样的四极杆质谱仪进行测定(简称Redox-MIMS法)。结果表明,Redox-MIMS法在氨基磺酸还原剂浓度为80~100 mmol/L时还原效率最好;方法的检测限约为0.5μmol/L,精密度为0.8%,工作曲线的线性范围可以达到0~150μmol/L。相对于次溴酸钠-碘氧化法,Redox-MIMS法反应条件温和,反应试剂相对易得,产物为^(29)N_(2),有效解决了^(30)N_(2)分析的一系列问题,并显著提高了测定效率(2 min/样品)。分别采用Redox-MIMS法和次溴酸钠-碘氧化法测定莱州湾沉积物实际样品,两种方法所测得的DNRA速率以及DNRA占异化硝酸盐还原的比例均无显著性差异,证明Redox-MIMS法是一种准确、高效地测定^(15)N加富培养样品中^(15)N H_(4)^(+)的方法。

活性污泥体系中C/N/S对硝酸盐还原过程的影响

采用序批式活性污泥反应器(ASBR),通过调整进水C/N和S/N,在活性污泥体系中探究电子受体有限的条件下,不同电子供体(有机物或者S^(2-))对反硝化和硝酸盐氮异化还原成铵(DNRA)过程的影响.结果表明:较高的C/N进水条件,有利于反硝化过程的进行;而较高的S/N进水条件,更有利于DNRA过程的发生;DNRA过程的特征产物NH_(4)^(+)-N,在C/N/S=2:2:3、2:2:4条件下的出水中较明显,其中C/N/S=2:2:4条件下,NH_(4)^(+)-N浓度达到最高为10.65mg/L.说明在电子受体有限时,过量的电子供体可促使反硝化向DNRA过程转变.采用16SrRNA分子生物学技术对不同C/N/S下的微生物菌群结构进行分析,发现与氮还原相关的Proteobacteria、Anaerolineae、Bacteroidia、Actinobacteria等菌群丰度较高,且Actinobacteria菌与DNRA过程相关.不同电子供体环境下氮转移途径的研究可为污水处理过程中碳,氮,硫的同步去除提供指导.

还原态硫介导沉积物-水系统硝酸盐还原过程研究

沉积物-水系统中存在着硫元素与反硝化(DN)、硝酸盐异化还原成铵(DNRA)过程的耦合。通过向构建的沉积物-水微宇宙系统依次投加0(N组)、50(L组)和75 mg·L^(-1)(H组)还原态硫,解析各形态氮在上覆水、间隙水和沉积物中的浓度变化与微生物群落结构,以揭示还原态硫对反硝化、硝酸盐异化还原成铵过程的影响。结果显示,还原态硫投加量分别为50和75 mg·L^(-1)时,系统分别有38.02%和33.27%还原态硫被转化为SO_(4)^(2-)。硫氧化作用促进了反硝化的发生,导致L和H组总氮分别比N组减少11%和8%;但是对DNRA过程没有显著影响。此外,具有硫自养反硝化功能的Thiobacillus和Dechloromonas相对丰度之和随着还原态硫浓度增加而上升,N、L和H组两者相对丰度之和分别为5.69%、6.52%和8.70%;而N、L和H组异养硝酸盐还原菌(HNRB)相对丰度分别为0.98%、0.91%和1.05%,其中,DNRA细菌相对丰度均较低(不超过1%),且不受还原态硫浓度的影响。此结果进一步印证了系统中硝酸盐还原以硫自养反硝化过程为主。

EDTA-2Na/Fe(Ⅱ)对自养生物体系下硝酸盐还原过程的影响

采用厌氧序批式生物膜反应器(ASBBR),以固定浓度的硝酸盐和硫酸亚铁为基质,按不同梯度条件添加EDTA-2Na,进行长时间的培养驯化,研究铁盐脱氮的启动过程,同时探究不同EDTA-2Na/Fe(Ⅱ)对铁自养反硝化过程以及硝酸盐异化还原为铵(DNRA)的影响.结果表明:经过65d的培养驯化,反应器成功稳定运行.当EDTA-2Na/Fe(Ⅱ)<1.50时,反应器只进行铁自养反硝化过程,NO_(3)^(-)-N去除率最高仅为71.70%;当EDTA-2Na/Fe(Ⅱ)≥1.50时,反应器同时进行铁自养反硝化与DNRA过程,NO_(3)^(-)-N去除率最高为99.70%.值得注意的是,在EDTA-2Na/Fe(Ⅱ)=1.50时,铁自养反硝化速率达到最大值1.63mg/(L·h)的同时,DNRA的产氨量也达到最大值9.75mg/L.Visual MINTEQ模拟结果表明:EDTA-2Na与Fe(Ⅱ)的摩尔比会影响进水中EDTA-2Na与Fe(Ⅱ)的存在形态,物质的量比越大,FeEDTA^(2)度越高,Fe(Ⅱ)的生物可利用性越强.通过对不同样本进行微生物种群分析,发现优势菌属有Brucella、Castellaniella、Ochrobactrum、Pseudomonas、Citrobacter,前4种菌属均与反硝化过程有关,Citrobacter菌属与DNRA过程有关,且该菌属只在EDTA-2Na/Fe(Ⅱ)=1.50和1.75两个条件下出现.上述研究结果可为更深入探究DNRA与反硝化之间的作用关系提供参考.

Nitrous Oxide and Methane Emissions as Affected by Water,Soil and Nitrogen

Specific management of water regimes, soil and N in China might play an important role in regulating N2O and CH4 emissions in rice fields. Nitrous oxide and methane emissions from alternate non-flooded/flooded paddies were monitored simultaneously during a 516-day incubation with lysimeter experiments. Two N sources (15N-(NH4)2SO4 and 15N-labeled milk vetch) were applied to two contrasting paddies: one derived from Xiashu loess (Loess) and one from Quaternary red clay (Clay). Both N2O and CH4 emissions were significantly higher in soil Clay than in soil Loess during the flooded period. For both soil, N2O emissions peaked at the transition periods shortly after the beginning of the flooded and non-flooded seasons. Soil type affected N2O emission patterns. In soil Clay, the emission peak during the transition period from non-flooded to flooded conditions was much higher than the peak during the transition period from flooded to non-flooded conditions. In soil Loess, the emission peak during the transition period from flooded to non-flooded conditions was obviously higher than the peak during the transition period from non-flooded to flooded conditions except for milk vetch treatment. Soil type also had a significant effect on CH4 emissions during the flooded season, over which the weighted average flux was 111 mg C m-2 h-1 and 2.2 mg C m-2 h-1 from Clay and Loess, respectively. Results indicated that it was the transition in the water regime that dominated N2O emissions while it was the soil type that dominated CH4 emissions during the flooded season. Anaerobic oxidation of methane possibly existed in soil Loess during the flooded season.