茭白田坑面水和渗漏水中氮素变化动态研究

茭白是黄浦江上游地区广泛种植的一种水田蔬菜.通过测坑定位试验,研究了茭白田坑面水和渗漏水中氮素变化动态和流失规律.结果表明,各处理茭白田坑面水中氮素形态以NH+4\|N为主,施肥后1～3 d,其占TN比例可达90%以上;渗漏水中氮素形态主要以NO-3\|N为主,施肥后呈现先上升后下降的趋势.通过增施有机肥、减少20%的无机氮肥用量可使坑面水TN减少20.74%,渗漏水中NO-3\|N减少16.10%,减少了氮素流失,且对茭白产量没有显著影响.、＝     

上海郊区稻田氮素流失研究

通过测坑和大田小区试验，研究了上海郊区稻田氮素排水流失和渗漏流失的特征、相关因素和流失负荷。结果表明，稻田综合排水TN为6.55mg／L，流失负荷为16．68kg／hm^2，以铵态氮为主，稻田氮素的排水流失负荷为16．68kg／hm^2。稻田渗漏水氮浓度与前茬作物有关，草莓和蔬菜高，麦茬低，TN为5．73mg／L，渗漏负荷为22．92kg／hm^2，其中硝态氮占50％左右。稻田氮素总流失负荷占稻季化肥用量的13．23％。测坑和大田试验都证明，施用有机肥可较多地减少稻田氮素流失量。     

农田氮素流失模型的构建与应用

农田氮素流失一直是困扰农业生产发展和影响生态平衡的一个重要问题，当前世界各国致力于研究提高氮肥利用率和减少氮素损失的方法与途径，但是仍没有一个普遍适用的模型能定量化地阐明氮素流失的规律与特征。综述近年来国内外在农田氮素流失方面的定量方法与模型构建等研究成果，同时提出该领域亟待解决的问题。     

农田氮素淋溶损失影响因素及防治对策研究

农田氮素损失是造成农业非点源污染的主要原因之一,其中由于大量施用氮肥引起的土壤氮素淋溶损失又是农田氮素损失的重要途径.因此,农田氮素损失研究已成为国际土壤化学和环境科学领域研究的热点问题之一.根据近年来国内外在农田氮素运移领域的研究成果,从降雨和灌溉、施肥状况、土壤性质、耕作方式、作物种类和种植方式等方面分析了影响农田氮素淋溶损失的主要因素,提出了改进施肥方式、优化氮肥管理、推广缓释氮肥以及改善土地利用方式等提高氮肥利用率、减小氮素淋溶损失的防治对策.     

铁炭复配修复地下水中NO3^--N的条件研究

采用了铁炭复配修复地下水中NO3^--N,探讨了实验条件对修复效果的影响。结果表明,在pH值近中性条件（初始pH 6.42）下,反应时间为1 h时NO3^--N修复率达到60.85%;Fe/C=1∶1时介质最佳用量分别为45 g;Fe/C=1/1.5时修复率为72.80%;反应速率在高振荡强度下大于低振荡强度;氧化铜的催化效果最好,可使修复率提高7.5个百分点。铁炭复配介质修复地下水中NO3^--N是有效可行的,修复率随反应时间的增加而提高,在Fe/C=1∶1时修复率与介质用量呈正相关,无限减小Fe/C比并不能无限提高修复率,振荡强度对修复具有显著影响,低振荡强度下的修复过程较高强度存在滞后现象,并非所有金属氧化物催化剂对铁炭修复NO3--N均有促进作用。     

环保型节氮肥料——脲铵在晚稻上的施用效果研究

在晚稻上施用脲铵与尿素,探索脲铵和尿素对水稻产量与氮肥吸收利用率(REN)的影响效果.结果表明:(1)尽管两种氮肥含氮量不同,但施用脲铵处理的折施纯氮量比尿素处理减少34.78％,晚稻产量并不减少,反而略有增加.(2)为了保证水稻产量、提高REN,当地水稻种植选择脲铵代替尿素作为氮肥效果较好,且推荐施用脲铵量为450～525 kg/hm2为宜.(3)施用脲铵量较高的REN优于施用量较低,施用脲铵525～600 kg/hm2(折施纯氮量为157.5～180.0 kg/hm2)时,REN为34％左右；施用脲铵375～450 kg/hm2时,REN约低5百分点.(4)在不施用有机肥料的条件下,从植株吸收氮量看,折施纯氮量180～200 kg/hm2,才能达到氮素收支基本平衡.因此,适量施用脲铵并配施有机肥或稻草还田,可以缓解氮素不平衡的问题.     

氮肥对污染农田土壤中铅的调控效应

用铅污染农田土壤做盆栽试验,研究了氮肥品种和施用量对小白菜吸收铅及土壤中铅形态的影响.结果表明,在氮肥施用量相同的条件下,施用不同形态氮肥对小白菜地上部及根系吸收铅有显著影响;适量的NH4NO3不会对小白菜地上部造成显著影响,增施Ca(NO3)2也不会造成小白菜地上部含铅量的继续增加;各施氮处理的土壤pH较不施氮处理的土壤pH均有不同程度的降低,且以(NH4)2SO4处理的土壤pH下降幅度最大,施用Ca(NO3)2的处理的土壤pH变化不显著;氮肥在一定程度上会影响土壤中各形态含铅量,其中对交换态、碳酸盐结合态、无定形氧化锰结合态,无定形氧化铁结合态及有机结合态含铅量影响较大,但并未改变各形态铅的分布顺序;小白菜吸收的铅主要来源于土壤中的交换态铅,但也可吸收部分碳酸盐结合态铅、铁锰氧化物结合态铅及有机结合态铅,甚至可吸收部分残渣态铅.     

农田包气带土层的脱氮防护探讨

施用氮肥是农业增产的重要手段,广施氮肥易引起包气带土层和地下水中的氮素污染,开展有关包气带土层中的氮素转化、消散以及脱氮防护的相关工作具有重要意义.选择河北山前平原较典型的包气带土层,依托野外试验田区构建的原状渗透土层系统和室内构建的一系列移位原状土柱系统,探索采用向这些土层中施入一定的硝态氮溶液,及配合同步测定土壤的...     

农业非点源污染氮素流失研究进展

从氮素流失的途径、影响因素和研究方法等3个方面对非点源污染氮素流失的相关研究进行了总结。指出地表径流、农田排水和淋溶是氮素流失的3条主要途径;降雨、坡度、施肥、耕作方式、土壤理化性质和管理模式等是影响氮素流失的关键因素;基于野外观测与模拟实验、查阅文献资料建立负荷估算模型是氮素流失定量研究的重要方法。最后,还对今后的研究重点进行了展望。     

缺氧反硝化-好氧串联系统对难降解PVA退浆废水的试验研究

研究了投加硝态氮NO3^--N对缺氧反硝化-好氧和缺氧水解-好氧串联系统处理印染PVA退浆废水的效果。结果表明，缺氧反硝化投加硝态氮NO3^--N比缺氧水解-好氧对CODCr的去除率在缺氧池、好氧池中均提高了30％，缺氧反硝化-好氧工艺二沉池出水经生物碳处理后，CODCr，的去除率达90％。C：N：P的比例合适与否是处理印染PVA退浆废水成功的关键。     

Fluxes of oxidised and reduced nitrogen above a mixed coniferous forest exposed to various nitrogen emission sources

Concentrations of nitrogen gases (NH(3), NO(2), NO, HONO and HNO(3)) and particles (pNH(4) and pNO(3)) were measured over a mixed coniferous forest impacted by high nitrogen loads. Nitrogen dioxide (NO(2)) represented the main nitrogen form, followed by nitric oxide (NO) and ammonia (NH(3)). A combination of gradient method (NH(3) and NO(x)) and resistance modelling techniques (HNO(3), HONO, pNH(4) and pNO(3)) was used to calculate dry deposition of nitrogen compounds. Net flux of NH(3) amounted to -64 ng N m(-2) s(-1) over the measuring period. Net fluxes of NO(x) were upward (8.5 ng N m(-2) s(-1)) with highest emission in the morning. Fluxes of other gases or aerosols substantially contributed to dry deposition. Total nitrogen deposition was estimated at -48 kg N ha(-1) yr(-1) and consisted for almost 80% of NH(x). Comparison of throughfall nitrogen with total deposition suggested substantial uptake of reduced N (+/-15 kg N ha(-1) yr(-1)) within the canopy.     

关中清灌区农田生态系统污染现状研究

对陕西关中地区清灌区土壤、粮食、地下水及农田退水中的重金属、含氮化合物等污染物进行了分析研究,结果表明：灌区土壤重金属含量在陕西土壤背景值范围内,主要粮食作物尚未受到污染（除F外）,但地下水已受到重金属、含氮化合物的污染。同时,灌区农田退水中三氮含量较高,直接排放渭河水体后,影响了渭河水质。另外还发现灌溉能减低土壤F污染。     

Nitrogen biogeochemistry in the Adirondack Mountains of New York: hardwood ecosystems and associated surface waters

Studies on the nitrogen (N) biogeochemistry in Adirondack northern hardwood ecosystems were summarized. Specific focus was placed on results at the Huntington Forest (HFS), Pancake-Hall Creek (PHC), Woods Lake (WL), Ampersand (AMO), Catlin Lake (CLO) and Hennessy Mountain (HM). Nitrogen deposition generally decreased from west to east in the Adirondacks, and there have been no marked temporal changes in N deposition from 1978 through 1998. Second-growth western sites (WL, PHC) had higher soil solution NO(3-) concentrations and fluxes than the HFS site in the central Adirondacks. Of the two old-growth sites (AMO and CLO), AMO had substantially higher NO(3-) concentrations due to the relative dominance of sugar maple that produced litter with high N mineralization and nitrification rates. The importance of vegetation in affecting N losses was also shown for N-fixing alders in wetlands. The Adirondack Manipulation and Modeling Project (AMMP) included separate experimental N additions of (NH4)2SO4 at WL, PHC and HFS and HNO3 at WL and HFS. Patterns of N loss varied with site and form of N addition and most of the N input was retained. For 16 lake/watersheds no consistent changes in NO(3-) concentrations were found from 1982 to 1997. Simulations suggested that marked NO(3-) loss will only be manifested over extended periods. Studies at the Arbutus Watershed provided information on the role of biogeochemical and hydrological factors in affecting the spatial and temporal patterns of NO(3-) concentrations. The heterogeneous topography in the Adirondacks has generated diverse landscape features and patterns of connectivity that are especially important in regulating the temporal and spatial patterns of NO(3-) concentrations in surface waters.     

Nitric oxide emissions from conventional vegetable fields in southeastern China

We conducted multi-year observations of nitric oxide (NO) fluxes from typical vegetable fields in the Yangtze River delta, which is located in southeastern China. Flux measurements were performed manually twice per week at intervals of 2–3 days, in both fertilized and unfertilized fields, over an investigation period of 1448 days (September 2004–August 2008). In total, twelve vegetable-growing periods and a short fallow period were investigated. On average, the NO fluxes from the fertilized plots were 21 times higher than fluxes from the unfertilized plots (p < 0.001). Peak NO emissions usually occurred soon after the addition of nitrogenous fertilizer. Peak emissions took place during about 15% of the whole investigation time, but contributed to approximately 89% of the total NO release. The annual background NO emissions (from fields without nitrogen amendment) were observed at 0.290 ± 0.019 (standard deviation of 3 observations) kg N ha^?1. The total amounts of NO emitted during the individual vegetable-growing periods correlated positively and exponentially with the products of seasonal mean soil temperatures and nitrogen addition rates (R² = 0.87, p < 0.001). The mean direct NO emission factor (EF_d, the loss rate of fertilizer nitrogen via NO emissions) for the four-year period was determined to be 0.51% ± 0.11% (standard error of 3 observations). The EF_ds of individual vegetable-growing seasons ranged from 0.05% to 1.24%, varying linearly and positively with the products of seasonal mean soil temperatures and nitrogen addition rates (R² = 0.58, p < 0.01). The observed interaction of soil temperature and nitrogen addition on NO emission in seasonal totals and EF_ds occurred in soils with moisture contents ranging from 55% to 100% water-filled pore space (mean: 79%; standard deviation: 9%). The results of this study indicate that when other conditions remain relatively stable, the direct emission factor, a key parameter for compiling an inventory of NO emissions from vegetable fields, may vary with not only soil temperature but also nitrogen addition.     

Responses to ammonium and nitrate additions by boreal plants and their natural enemies

Separate effects of ammonium (NH4+) and nitrate (NO3-) on boreal forest understorey vegetation were investigated in an experiment where 12.5 and 50.0 kg nitrogen (N) ha(-1) year(-1) was added to 2 m2 sized plots during 4 years. The dwarf-shrubs dominating the plant community, Vaccinium myrtillus and V. vitis-idaea, took up little of the added N independent of the chemical form, and their growth did not respond to the N treatments. The grass Deschampsia flexuosa increased from the N additions and most so in response to NO3-. Bryophytes took up predominately NH4+ and there was a negative correlation between moss N concentration and abundance. Plant pathogenic fungi increased from the N additions, but showed no differences in response to the two N forms. Because the relative contribution of NH4+ and NO3- to the total N deposition on a regional scale can vary substantially, the N load a habitat can sustain without substantial changes in the biota should be set considering specific vegetation responses to the predominant N form in deposition.     

Nitric oxide emission from a typical vegetable field in the Pearl River Delta, China

Croplands contribute to atmospheric nitric oxide (NO), but very limited data are available about NO fluxes from intensively managed croplands in China. In this study, NO fluxes were measured in a typical vegetable field planted with flowering Chinese cabbage (Brassica campestris L. ssp. Chinensis var. utilis Tsen et Lee), which is the most widely cultivated vegetable in Guangdong province, south China. NO emission drastically increased after nitrogen fertilizer application, and other practices involving loosening the soil also enhanced NO emission. Mean NO emission flux was 47.5 ng N m⁻² s^–1 over a complete growth cycle. Annual NO emission from the vegetable field was about 10.1 kg N ha⁻¹ yr⁻¹. Fertilizer-induced NO emission factor was estimated to be 2.4%. Total NO emission from vegetable fields in Guangdong province was roughly estimated to be 11.7 Gg N yr⁻¹ based on the vegetable field area and annual NO emission rate, and to be 13.3 Gg N yr⁻¹ based on fertilizer-induced NO emission factor and background NO emission. This means that NO emission from vegetable fields was approximately 6% of NO_x from commercial energy consumption in Guangdong province.     

NOX fluxes from several typical agricultural fields during summer-autumn in the Yangtze Delta,China

NO_X fluxes from three kinds of vegetable lands and a rice field were measured during summer–autumn in the Yangtze Delta, China. The average NO fluxes from the rice fields (RF), celery field (CE), maize field (MA) and cowpea field (CP) were 4.1, 30.8, 54 and 32.2 ng N m^?2 s^?1, respectively; and the average NO₂ fluxes were ?2.12, 0.68, 1.33 and 0.5 ng N m^?2 s^?1, respectively. The liquid N fertilizer (the mixture of swine excrement and urine) which is widely applied to vegetable lands by Chinese farmers was found to quickly stimulate NO emission, and have significant contribution to NO emission from the investigated vegetable lands. Apparent linearity correlations were found between NO₂ fluxes and the ambient concentrations of the rice fields, with a compensation point of about 2.84 μg m^?3. Total emissions of NO during summer–autumn time from this area were roughly estimated to be 4.1 and 8.4 Gg N for rice field and vegetable lands, respectively.     

溶解氧对河流底泥中三氮释放的影响

作为内源污染的底泥沉积物中营养物的释放引起了越来越多的关注。通过大型静态土柱模拟实验,研究氮在上覆水和孔隙水中的分布特性和释放特性。在控制氧气条件、底泥有机质含量和粒径大小的条件下,连续观测氨态氮、亚硝态氮和硝态氮的浓度及其垂向分布特性。结果发现：时间分布上,通氧条件明显影响水体底泥中三氮释放与反硝化作用达到平衡的时间;垂向分布上,三期实验的上覆水的无机氮以氨态氮为主,不同的通氧条件下,各柱的孔隙水的三氮浓度比上覆水高,且三氮在沉积物中随深度增加而增加;氨态氮和硝态氮浓度则以孔隙水的为高,随深度增加而增加;低溶解氧水平加快底泥释放氨氮速度和增大释放量。     

Challenges in quantifying biosphere-atmosphere exchange of nitrogen species

Recent research in nitrogen exchange with the atmosphere has separated research communities according to N form. The integrated perspective needed to quantify the net effect of N on greenhouse-gas balance is being addressed by the NitroEurope Integrated Project (NEU). Recent advances have depended on improved methodologies, while ongoing challenges include gas-aerosol interactions, organic nitrogen and N(2) fluxes. The NEU strategy applies a 3-tier Flux Network together with a Manipulation Network of global-change experiments, linked by common protocols to facilitate model application. Substantial progress has been made in modelling N fluxes, especially for N(2)O, NO and bi-directional NH(3) exchange. Landscape analysis represents an emerging challenge to address the spatial interactions between farms, fields, ecosystems, catchments and air dispersion/deposition. European up-scaling of N fluxes is highly uncertain and a key priority is for better data on agricultural practices. Finally, attention is needed to develop N flux verification procedures to assess compliance with international protocols.     

Light-induced disappearance of nitrite in the presence of iron (III)

Understanding of rapid disappearance of nitrite in natural waters and its impact on nitrogen natural cycling has remained limited. We found that NO2- disappeared rapidly in pH 3.2 aqueous Fe(III) solutions both in sunlight and in 356 nm light. Quantum yields of the NO2- loss at 356 nm were 0.049-0.14 for initial levels of 10-80 microns NO2- and 200 microns Fe(III). The NO2- loss (at 356 nm) followed apparent first-order kinetics. The rate constants were 1.3 x 10(-3) (40 microns NO2-) and 4.1 x 10(-4) s-1 (80 microns NO2-) for 100 microns Fe(III), and 2.3 x 10(-3) (40 microns NO2-) and 7.5 x 10(-4) s-1 (80 microns NO2(-1)) for 200 microns Fe(III) (t1/2 = 8.7, 27.9, 5.1, and 15.3 min, respectively). The rate constants were directly proportional to [Fe(III)]0 and inversely proportional to [NO2-]0. Agreement between the rate constants obtained experimentally and those calculated mechanistically supports the hypothesis that NO2- was oxidized to NO2 by .OH radicals from photolysis of FeOH2+ complexes, and at high [NO2-]0 (e.g., 80 microns) relative to [Fe(III)]0, hydrolysis of NO2 or N2O4 to form NO3- and NO2- could be significant. This study showed that light and Fe(III)-induced oxidation of NO2- (rate = approximately 10(-1)-10(-2) microns s-1) was more rapid than its direct photolysis (rate = approximately 10(-4) microns s-1), and the photolysis could be a significant source of .OH radicals only in cases where the Fe(III) level is much lower than the NO2- level ([Fe(III)]/[NO2-] < 1/80). This study suggests that the light and Fe(III)-induced oxidation of NO2- would be one potential important pathway responsible for the rapid transformation of NO2- in acidic surface waters, especially those affected by acid-mine drainage or volcanic activities. This study also may be of interest for modeling certain acidic atmospheric water environments.