植物排放N2O和CH4的研究

N2O和CH4是2种重要的温室气体,但其排放源尚未得到充分鉴别.1990年和2006年先后报道植物能排放N2O和CH4,并日益受到广泛的关注.然而,迄今为止对植物排放这2种气体的研究均是分开单独进行的.该文以8种陆生草本植物为研究对象,首次同步考察了新鲜离体植物地上部排放N2O和CH4的通量.研究结果表明:8种植物均能排放这2种气体.其中,黑麦草(Lolium perenne)、抱茎苦荬菜(Ixendium sonchifolium)和菠菜(Spinacia oleracea)的CH4通量较高,分别为165.38、52.28和21.64 ngCH4.g-1dw·h-1;抱茎苦荬菜、蒙古蒿(Artemisia mongolica)、大豆(Glycine max)和菠菜的N2O通量较高,分别为7.19、6.92、5.44和4.05 ngN2O·g-1dw.h-1.研究结果不仅为植物本身既能排放N2O又能排放CH4在植物中可能具有普遍性提供了进一步的实验依据,而且为深入研究其机理找到了几种适宜的植物种(如抱茎苦荬菜、菠菜).     

植物排放N2O和CH4的研究

N₂O和CH₄是2种重要的温室气体, 但其排放源尚未得到充分鉴别。1990年和2006年先后报道植物能排放N₂O和CH₄, 并日益受到广泛的关注。然而, 迄今为止对植物排放这2种气体的研究均是分开单独进行的。该文以8种陆生草本植物为研究对象, 首次同步考察了新鲜离体植物地上部排放N₂O和CH₄的通量。研究结果表明: 8种植物均能排放这2种气体。其中, 黑麦草(Lolium perenne)、抱茎苦荬菜(Ixeridium sonchifolium)和菠菜(Spinacia oleracea)的CH₄通量较高, 分别为165.38、 52.28和21.64 ngCH₄·g^–1dw·h^–1; 抱茎苦荬菜、蒙古蒿(Artemisia mongolica)、大豆(Glycine max)和菠菜的N₂O通量较高, 分别为7.19、6.92、5.44和4.05 ngN₂O·g^–1dw·h^–1。研究结果不仅为植物本身既能排放N₂O又能排放CH₄在植物中可能具有普遍性提供了进一步的实验依据, 而且为深入研究其机理找到了几种适宜的植物种(如抱茎苦荬菜、菠菜)。     

DCD不同施用时间对小麦生长期N2O排放的影响

通过田间试验,采用静态箱法研究相同施肥条件下,DCD不同施用时间(基肥配施,追肥配施,基追肥按比例配施)对麦季N2O排放的影响.结果表明,小麦生长期施肥配施DCD减少麦季N2O排放.从小麦整个生长季来看,与尿素处理相比,基肥配施减少N2O排放21％,追肥配施减少N2O排放26％,基追肥按比例配施减少N2O排放35％,方差分析均达显著水平(P＜0.05),其中基肥配施主要减少小麦播种-返青期N2O排放,追肥配施主要减少小麦返青-成熟期N2O排放,而基追肥按比例配施DCD减少整个小麦生长季N2O排放.在小麦的整个生长阶段,施加DCD处理的土壤NH+4-N浓度和表观硝化率均高于未施加DCD的处理,且土壤NH+4-N浓度随时间的延长而降低.在小麦播种-返青期,基肥配施处理和基追肥按比例配施处理土壤NH+4-N浓度和表观硝化率高于追肥配施处理和对照处理;在小麦的返青-成熟期,追肥配施处理和基追肥按比例配施处理土壤NH+4-N浓度和表观硝化率高于基肥配施处理和对照处理.从小麦产量来看,与尿素处理相比,基肥配施和基追肥按比例配施显著增加小麦产量,而追肥配施处理小麦产量无显著性差异.基追肥按比例配施DCD在提高小麦产量的同时显著减少N2O排放,具有大田推广的现实意义;基肥与追肥配施DCD对N2O减排效果除了与施用时间有关外,还应将降雨或灌溉量的年际变化考虑在内.     

长效氮肥施用对黑土水旱田CH4和N2O排放的影响

通过在黑土玉米地与水稻田施用长效氮肥后发现 ,长效碳酸氢铵 (长碳 )与长效尿素(长尿 )能显著减少黑土玉米地N2 O的排放。与施用普通尿素相比 ,其排放量分别减少了5 9 2 %和 73 3%。长碳和长尿还能促进黑土玉米地对CH4的吸收作用。黑土水稻田施用长尿后 ,N2 O的排放减少了 6 1%。而CH4的排放却略有增加     

黑土稻田CH4与N2O排放及减排措施研究

通过对黑土稻田CH₄和N₂O排放的观测,发现水稻生长季CH₄和N₂O排放量低于全国其它地区稻田CH₄和N₂O排放之间存在互为消长关系(r=-0．513,P<0．05),但在同样施肥水平条件下,间歇灌溉与长期淹灌相比,CH₄排放明显减少而N₂O略有增加,其相对综合温室效应被大大减少且水稻产量未受影响。为此,间歇灌溉可作为减少稻田温室气体排放的水分管理措施。另外,通过对CH₄和N₂O排放的相关微生物过程探讨,揭示产甲烷菌数与CH4排放问呈显著性正相关(R²=0．82,P<0．05),硝化菌数和反硝化菌数与N2O排放有重要关系。     

开放式空气CO2增高对稻田CH4和N2O排放的影响

在FACE(free aircarbondioxideenrichment)平台上 ,采用静态暗箱 气相色谱法观测研究了大气CO2 浓度增加对稻田CH4和N2 O排放的影响 .结果表明 ,在 15 0和 2 5 0kgN·hm-2 两种氮肥水平下大气CO2 浓度增加 2 0 0 μmol·mol-1均明显促进水稻生长 ,水稻生物量积累 .大气CO2 浓度增加对 15 0和 2 5 0kgN·hm-2 两种氮肥水平下稻田CH4排放均无显著影响 ,并简要分析了与现有文献报道结果不一致的原因 .大气CO2 浓度增加也未导致 15 0和 2 5 0kgN·hm-2 两种氮肥水平下稻田N2 O排放的明显变化 ,与大多数研究结果一致 .     

外源氮对沼泽湿地CH4和N2O通量的影响

三江平原沼泽湿地受到大气沉降、地表径流、农业排水等外源氮素的输入,对湿地生态系统CH4和N2O通量有重要影响。采用野外原位施肥试验模拟外源氮输入,设0,60,120,240kgN·hm^-24种试验处理,探讨外源氮对沼泽湿地CH4和N2O通量的影响。结果表明,外源氮促进了CH4和N2O排放。与对照处理比较,各施氮水平CH4平均排放通量分别增加了181％,254％和155％,N2O排放通量分别增加了21％,100％和533％。外源氮输入对CH4排放的季节变化形式影响不大,而N2O的季节变化形式随着氮输入表现出波动变化的趋势。不同施氮水平对CH4排放的促进作用与植物生长阶段和产CH4的微生物过程密切相关,N2O排放通量随氮输入量呈指数增加（R^2=0．97,P〈0．01）。外源氮通过影响湿地微生物过程来进一步影响CH4和N2O的排放。     

稳定性氮肥配合秸秆还田对水稻产量及N2O和CH4排放的影响

以中国科学院辽宁沈阳农田生态系统国家野外科学观测研究站连续两年的试验平台为依托,以潮棕壤为供试土壤,开展了稳定性氮肥配合秸秆还田对水稻产量及N₂O和CH₄排放的影响研究,设置对照(CK)、尿素(U)、尿素+脲酶抑制剂+硝化抑制剂(U+I)、秸秆还田(S)、秸秆还田+尿素(S+U)、秸秆还田+尿素+脲酶抑制剂+硝化抑制剂(S+U+I)6个处理.结果表明: 与CK相比,尿素显著提高了水稻产量、N₂O和CH₄累积排放及全球增温潜势.硝化抑制剂和脲酶抑制剂与尿素配施可显著减缓N₂O的累积排放.秸秆还田显著增加了N₂O和CH₄累积排放、全球增温潜势和温室气体排放强度.S+U+I处理水稻产量最高,但温室气体排放强度也显著高于其他处理;U+I处理产量略低于S+U+I,但温室气体排放强度最小.秸秆单独还田处理作物产量与对照相比无显著差异.在东北潮棕壤发育的水田中,S+U+I和U+I是相对较优的施肥模式.     

内蒙古草甸草原CH4和N2O排放通量的时间变异

 1998年6月1日、7月2日、8月3日和9月1日用静态箱-气相色谱法对内蒙古锡林河流域草甸草原CH4和N2O排放通量的昼夜观测表明,天然草原是N2O的源、CH4的汇,其排放和吸收具有明显的昼夜变化规律。4次昼夜观测的结果还表明,草甸草原排放N2O和吸收CH4的能力具有强烈的季节变化规律     

反刍家畜及其排泄物对N2O和CH4排放的贡献

了解反刍动物及其排泄物对温室气体的贡献以及主要影响因素对于认识全球气候变化及寻找减缓措施都具有重要的社会、经济和生态学意义.本文在综述了大量国内外相关文献的基础上,提出提高家畜营养水平和均衡营养,特别是在天然草原上增加豆科牧草的比例,并通过在饲料中适量添加中链脂肪酸等添加剂,是提高家畜的生产性能、降低CH4排放量的有效措施.同时指出,由于在家畜排泄物处理和利用过程中,降低一种温室气体的排放可能会增加另一种气体的排放,因此,应该根据它们对大气增温潜值的差异,将各种处理下温室气体换算成CO2-C,从而进行比较分析,通过调整综合措施以达到二者总释放量的最低水平;同时还应该考虑到所产生的NH3和亚硝酸盐/硝酸盐对大气和环境的污染.因此,如何提高反刍家畜的饲养与营养、调整放牧管理制度、改善草原群落结构,从而在提高个体生产性能的基础上达到降低家畜总饲养量,最终实现草原生态保护、家畜生产和温室气体排放综合考虑的折衷管理方案,是今后所要解决的科学问题.任何减缓温室气体排放的措施都应该以整个生产系统为基础,从而综合评价所采取措施的有效性.     

垦殖对沼泽湿地CH4和N2O排放的影响

三江平原是我国最大的沼泽化低平原,同时也是受人类活动影响最剧烈的区域之一。选取三江平原两类典型湿地-常年积水的毛果苔草(Carexlasiocapa)沼泽和季节性积水的小叶章(Deyeuxia angustifolia)草甸及其垦殖水田和旱田为研究对象,利用静态暗箱-气相色谱法进行CH4和N2O的田间原位观测。研究结果表明,垦殖导致沼泽湿地CH4排放量大幅度降低,而N2O排放量有所升高。三江平原沼泽湿地、水田、旱田的CH4排放量分别为329.56、94.82kg.hm-.2a-1和-1.37kg.hm-.2a-1,N2O排放量分别为1.93、2.09kg.hm-.2a-1和4.90kg.hm-.2a-1。沼泽湿地垦殖使CH4和N2O的综合温室效应降低,在20a到500a的时间尺度上,水田综合GWP为沼泽湿地的30.8%~37.9%,旱田综合GWP仅为沼泽湿地的6.0%~28.7%。垦殖同时也改变了沼泽湿地对大气CO2的源汇功能,2004年,小叶章草甸、水田和旱田碳排放量分别为-3.08、1.79t.hm-2和3.35t.hm-2,沼泽湿地垦殖为旱田后碳源的功能较水田更强。     

控释肥及其与尿素配合施用对水稻生长期N_2O排放的影响

通过田间试验,采用静态箱法研究相同施氮量条件下,施用尿素、控释肥及尿素与控释肥配施(尿素与控释肥以3:7配合施用)对稻田N2O排放的影响.结果表明:与单施尿素处理相比,配施处理和控释肥处理水稻生长期N2O排放量分别减少40.4%和59.6%(P<0.05),其中烤田期分别减少65.1%和83.9%;与配施处理相比,施用控释肥处理N2O排放量略微减少(P>0.05),其中烤田期减少53.9%.施用控释肥可增加水稻产量,与尿素处理相比,施用控释肥和配施处理水稻产量分别增加7.8%和9.8%(P>0.05).施用控释肥使土壤无机氮峰值出现时间延后,烤田期N2O排放减少.水稻生长期N2O排放通量与土壤氧化还原电位(Eh)和土壤温度均无明显相关性(P>0.05).     

控释肥及其与尿素配合施用对水稻生长期N2O排放的影响

通过田间试验,采用静态箱法研究相同施氮量条件下,施用尿素、控释肥及尿素与控释肥配施(尿素与控释肥以3∶7配合施用)对稻田N₂O排放的影响.结果表明：与单施尿素处理相比,配施处理和控释肥处理水稻生长期N₂O排放量分别减少40.4%和59.6%（P<0.05）,其中烤田期分别减少65.1%和83.9%;与配施处理相比,施用控释肥处理N₂O排放量略微减少（P>0.05）,其中烤田期减少53.9%.施用控释肥可增加水稻产量,与尿素处理相比,施用控释肥和配施处理水稻产量分别增加7.8%和9.8%（P>0.05）.施用控释肥使土壤无机氮峰值出现时间延后,烤田期N₂O排放减少.水稻生长期N₂O排放通量与土壤氧化还原电位（Eh）和土壤温度均无明显相关性（P>0.05）.     

双氢胺对土壤裂缝产生过程中N2O释放的影响

模拟稻田土壤在加入不同量的（NH4）2SO4和双氢按（DCD）抑制剂的溶液后先进行淹水培养,然后让土壤自然蒸发变干,直至土壤产生裂缝到裂缝稳定,最后在裂缝稳定后的复水的连续培养试验。通过模拟对土壤进行复杂的、动态的水分含量变化过程中试验,探讨双氢胺抑制剂对其N2O释放的影响。每天监测土体释放的N2O通量,以及渗漏液中溶解的N2O浓度和pH值。这些监测结果表明：在相同的水分管理条件下,土壤中没有氮肥加入,只有DCD加入的A处理释放N2O气体最少,其平均释放通量为340.91μgm^-2h^-1;土壤中有高剂量的氮肥和DCD加入的E处理释放N2O最多,其平均释放通量为9280.23μgm^-2h^-1。裂缝产生稳定后的复水能减少N2O向空气中的释放。渗漏液中的N2O浓度都是过饱和的。当土壤中肥料（NH4）2SO4加入量（每千克土壤中外加N≤3g）相对较少的情况下,DCD抑制剂能抑制裂缝产生过程中的N2O释放;当土壤中肥料（NH4）2SO4加入量（每千克土壤中外加N≥6g）相对较多的情况下,DCD抑制裂缝产生过程中的N2O释放效果不明显。此外还得出（NH4）2SO4和DCD的加入量比是10：1时,其抑制N2O排放的效果比（NH4）2SO4和DCD的加入量比分别是10：1.5和10：2要好。土体释放的N2O通量和渗漏液中溶解的N2O浓度之间不存在相关性,土体释放的N2O通量和渗漏液中的pH值之间也不存在相关性。但是渗漏液中的N：O浓度和pH值之间存在显著的正线性相关关系。     

Effect of oxic and anoxic conditions on nitrous oxide emissions from nitrification and denitrification processes

A lab-scale sequencing batch reactor fed with real municipal wastewater was used to study nitrous oxide (N(2)O) emissions from simulated wastewater treatment processes. The experiments were performed under four different controlled conditions as follows: (1) fully aerobic, (2) anoxic-aerobic with high dissolved oxygen (DO) concentration, (3) anoxic-aerobic with low DO concentration, and 4) intermittent aeration. The results indicated that N(2)O production can occur from both incomplete nitrification and incomplete denitrification. N(2)O production from denitrification was observed in both aerobic and anoxic phases. However, N(2)O production from aerobic conditions occurred only when both low DO concentrations and high nitrite concentration existed simultaneously. The magnitude of N(2) O produced via anoxic denitrification was lower than via oxic denitrification and required the presence of nitrite. Changes in DO, ammonium, and nitrite concentrations influenced the magnitude of N(2)O production through denitrification. The results also suggested that N(2)O can be produced from incomplete denitrification and then released to the atmosphere during aeration phase due to air stripping. Therefore, biological nitrogen removal systems should be optimized to promote complete nitrification and denitrification to minimize N(2)O emissions.     

Effects of an experimental drought on soil emissions of carbon dioxide, methane, nitrous oxide, and nitric oxide in a moist tropical forest

Changes in precipitation in the Amazon Basin resulting from regional deforestation, global warming, and El Niño events may affect emissions of carbon dioxide (CO₂), methane (CH₄), nitrous oxide (N₂O), and nitric oxide (NO) from soils. Changes in soil emissions of radiatively important gases could have feedback implications for regional and global climates. Here we report results of a large‐scale (1 ha) throughfall exclusion experiment conducted in a mature evergreen forest near Santarém, Brazil. The exclusion manipulation lowered annual N₂O emissions by >40% and increased rates of consumption of atmospheric CH₄ by a factor of >4. No treatment effect has yet been detected for NO and CO₂ fluxes. The responses of these microbial processes after three rainy seasons of the exclusion treatment are characteristic of a direct effect of soil aeration on denitrification, methanogenesis, and methanotrophy. An anticipated second phase response, in which drought‐induced plant mortality is followed by increased mineralization of C and N substrates from dead fine roots and by increased foraging of termites on dead coarse roots, has not yet been detected. Analyses of depth profiles of N₂O and CO₂ concentrations with a diffusivity model revealed that the top 25 cm soil is the site of most of the wet season production of N₂O, whereas significant CO₂ production occurs down to 100 cm in both seasons, and small production of CO₂ occurs to at least 1100 cm depth. The diffusivity‐based estimates of CO₂ production as a function of depth were strongly correlated with fine root biomass, indicating that trends in belowground C allocation may be inferred from monitoring and modeling profiles of H₂O and CO₂.     

Effects of an experimental drought and recovery on soil emissions of carbon dioxide,methane, nitrous oxide,and nitric oxide in a moist tropical forest

Changes in precipitation in the Amazon Basin resulting from regional deforestation, global warming, and El Niño events may affect emissions of carbon dioxide (CO₂), methane (CH₄), nitrous oxide (N₂O), and nitric oxide (NO) from soils. Changes in soil emissions of radiatively important gases could have feedback implications for regional and global climate. Here, we report the final results of a 5‐year, large‐scale (1 ha) throughfall exclusion experiment, followed by 1 year of recovery with natural throughfall, conducted in a mature evergreen forest near Santarém, Brazil. The exclusion manipulation lowered annual N₂O emissions in four out of five treatment years (a natural drought year being the exception), and then recovered during the first year after the drought treatment stopped. Similarly, consumption of atmospheric CH₄ increased under drought treatment, except during a natural drought year, and it also recovered to pretreatment values during the first year that natural throughfall was permitted back on the plot. No treatment effect was detected for NO emissions during the first 3 treatment years, but NO emissions increased in the fourth year under the extremely dry conditions of the exclusion plot during a natural drought. Surprisingly, there was no treatment effect on soil CO₂ efflux in any year. The drought treatment provoked significant tree mortality and reduced the allocation of C to stems, but allocation of C to foliage and roots were less affected. Taken together, these results suggest that the dominant effect of throughfall exclusion on soil processes during this 6‐year period was on soil aeration conditions that transiently affected CH₄, N₂O, and NO production and consumption.     

氢醌和双氰胺对种稻土壤N2O和CH4排放的影响

通过盆栽试验,研究了脲酶抑制剂氢醌（ＨＱ）、硝化抑制剂双氰胺（ＤＣＤ）及二者的组合（ＨＱ＋ＤＣＤ）对种稻土壤Ｎ２Ｏ和ＣＨ４排放的影响．结果表明,在未施麦秸粉时,所有施抑制剂的处理均较单施尿素的能显著减少水稻生长期供试土壤Ｎ２Ｏ和ＣＨ４的排放．特别是ＨＱ＋ＤＣＤ处理,其Ｎ２Ｏ和ＣＨ４排放总量分别约为对照的１／３和１／２．而在施麦秸粉后,该处理的Ｎ２Ｏ排放总量为对照的１／２,但ＣＨ４排放总量却较少差别．不论是Ｎ２Ｏ还是ＣＨ４的排放总量,施麦秸粉的都比未施的高出１倍和更多．因此,单从土壤源温室气体排放的角度看,将未腐熟的有机物料与尿素共施,并不是一种适宜的施肥制度．供试土壤的Ｎ２Ｏ排放通量,与水稻植株的ＮＯ－３Ｎ含量和土表水层中的矿质Ｎ量分别呈显著的指数正相关和线性正相关;ＣＨ４的排放通量则与水稻植株的生长量和土表水层中的矿质Ｎ量呈显著的线性负相关．在Ｎ２Ｏ与ＣＨ４的排放间,未施麦秸粉时存在着定量的相互消长关系;施麦秸粉后,虽同样存在所述关系,但难以定量化．     

Estimates of methane emissions from Chinese rice paddies by linking a model to GIS database

Methane is one of the principal greenhouse gases. Irrigated rice paddies are recognized as contributing to atmospheric methane concentration. Methane emissions from rice paddies are among the most uncertain estimates in rice-growing countries. Efforts have been made over the last decade to estimate CH₄ emissions from Chinese rice paddies via the model method. However, these estimates are very vague due to different models and upscaling methods. A reduction in these uncertainties may be achieved by coupling field-scale models with regional databases. The objective of this article is to develop a methodology of coupling a CH₄ emission model with regional databases by which CH₄ emissions from Chinese rice paddies can then be estimated. CH4MOD, a model for simulating CH₄ emissions from rice paddies with minimal input by using commonly available parameters, is of great potential in terms of upscaling as it has provided a realistic estimate of the observed results from various soils, climates and agricultural practices. By linking spatial databases to CH4MOD, CH₄ emissions from Chinese rice paddies in the 2000 rice-growing season were simulated on a day-by-day basis. The spatial databases were created by GIS with a spatial resolution of 10km10km, including soil sand percentage, amounts of crop straw and roots from the previous season and farm manure, the water management pattern, dates of rice transplanting and harvesting, acreage of rice planted, rice grain yield and daily air temperature. ARCGIS software was used to meet all GIS needs, including data access, projection definition, overlaying of different vector layers, creation of grids (a raster format of ARCGIS software) by converting vector data, and the data conversion between grids and ASCII formats. Methane emissions from rice paddies in mainland China in the 2000 rice-growing season were estimated to be 6.02 Tg (1 Tg = 10⁹ kg). Of the total, approximately 49% (2.93Tg) is emitted during the single rice-growing season, and 27% (1.63Tg) and 24% (1.46Tg) are from the early and late rice-growing seasons respectively. It was concluded that regional CH4 emissions from rice paddies could be estimated by coupling CH4MOD with regional databases with a high spatial resolution. A further effort should be made to improve the quality of the spatial databases, especially in terms of the amount of added organic matter and the water regime. It is also necessary to evaluate the uncertainties of the present estimates in order to improve the overall accuracy.