江西赣州站大气CO2和CH4浓度变化特征研究

通过分析2018年12月—2019年11月江西赣州站大气CO₂和CH₄浓度高精度在线观测资料,对其CO₂和CH₄浓度变化特征进行了研究,分析了区域大气输送的影响以及潜在排放源区分布特征.结果表明：研究期内赣州站CO₂和CH₄的平均浓度分别为433.1×10^-6和2142.5×10^-9.赣州站CO₂和CH₄浓度日变化均表现为日间低、早晚高,CO₂浓度日振幅在夏季最大,为29.7×10^-6,冬季最小,为6.9×10^-6.CH₄浓度日振幅在秋季最大,为145.1×10^-9,冬季最小,为41.4×10^-9.CO₂本底浓度季节变化表现为4—8月迅速下降,8—11月逐渐上升,最大值出现在1月,最小值出现在8月,季节振幅为26.2×10^-6.CH₄本底浓度季节变化表现为1—7月逐渐下降,7—9月逐渐上升,最大值出现在1月,最小值出现在7月,季节振幅为79.5×10^-9,基本可代表江西赣州地区混合均匀大气的CO₂和CH₄季节变化状况.与南昌站对比分析表明,赣州站各季节CO₂和CH₄本底浓度均低于南昌站.赣州地区CO₂和CH₄潜在源区主要分布在江西北部、湖北东部、安徽南部和珠江三角洲地区.     

农垦与放牧对内蒙古草原N2O、CO2排放和CH4吸收的影响

利用优选静态箱/气相色谱法(GC),首次对我国内蒙古草原典型地区进行了人类活动对N₂O、CO₂和CH₄交换通量影响的实验观测结果表明,农垦麦田N₂O平均排放通量比原始草原高出3倍,并改变了草甸草原为CO₂汇的性质,使其季节排放净通量以C计增加14.3 mg·(m²·h).随放牧强度的增加CO₂排放通量呈线性增长,轻牧会引起草原对CH₄吸收的大幅增加,而随着放牧压力的增大,增加值迅速回落.农垦麦田与草甸草原相比地-气间CH₄交换无显著变化,放牧强度对N₂O排放影响无显著规律.土壤湿度和温度是影响草原排放N₂O和CO₂、吸收CH4季节变化形式的关键因子,而人类活动仅影响排放强度.排放和吸收量年际间差异很大,但主要受降水的影响.N₂O和CO₂排放与CH₄吸收峰值相反现象普遍存在.     

Monitoring atmospheric nitrous oxide background concentrations at Zhongshan Station, east Antarctica

At present,continuous observation data for atmospheric nitrous oxide(N_2O) concentrations are still lacking,especially in east Antarctica.In this paper,nitrous oxide background concentrations were measured at Zhongshan Station(69°22′25″S,76°22′14″E),east Antarctica during the period of 2008–2012,and their interannual and seasonal characteristics were analyzed and discussed.The mean N_2O concentration was 321.9 n L/L with the range of 320.5–324.8 n L/L during the five years,and it has been increasing at a rate of 0.29% year-1.Atmospheric N_2O concentrations showed a strong seasonal fluctuation during these five years.The concentrations appeared to follow a downtrend from spring to autumn,and then increased in winter.Generally the highest concentrations occurred in spring.This trend was very similar to that observed at other global observation sites.The overall N_2O concentration at the selected global sites showed an increasing annual trend,and the mean N_2O concentration in the Northern Hemisphere was slightly higher than that in the Southern Hemisphere.Our result could be representative of atmospheric N_2O background levels at the global scale.This study provided valuable data for atmospheric N_2O concentrations in east Antarctica,which is important to study on the relationships between N2 O emissions and climate change.     

改进的大气CO2、CH4、N2O、CO在线观测FTIR系统

利用商用傅利叶变换红外光谱仪(FTIR)主机,与自动进样模块及标气模块集成,初步建立了一套可流程化、准确、高效分析大气CO2、CH4、CO和N2O的在线观测系统.测试结果表明,该商用FTIR主机具有良好的精度,但以仪器自带校正系数估算的结果绝对误差大,尤其CO的绝对误差可达38.8×10-9,无法满足在线观测要求.集成后的FTIR系统改用可溯源至国际标准的工作标气进行计算,有效降低了结果的绝对误差.动态及静态两种模式下各要素实测值与标称值的摩尔分数绝对误差为CO2≤0.11×10-6、CH4≤1.8×10-9、N2O≤0.15×10-9、CO≤0.5×10-9,能够满足大气在线观测需求.利用该FTIR集成系统进行6 d的模拟在线观测,采用动态流量模式(Flow)进样,每隔6 h穿插高、低浓度工作标气及目标气进样,用标气的标称值及系统更新的标气响应值计算样气及目标气结果.目标气CO2/CH4/N2O/CO的摩尔分数标准偏差分别为0.05×10-6、0.2×10-9、0.07×10-9、0.5×10-9,平均值与标称值之间的绝对误差分别为0.09×10-6、0.4×10-9、0.14×10-9、0.5×10-9.     

Methane and nitrous oxide emissions from a subtropical coastal embayment (Moreton Bay, Australia)

Surface water methane (CH₄) and nitrous oxide (N₂O) concentrations and fluxes were investigated in two subtropical coastal embayments (Bramble Bay and Deception Bay, which are part of the greater Moreton Bay, Australia). Measurements were done at 23 stations in seven campaigns covering different seasons during 2010-2012. Water-air fluxes were estimated using the Thin Boundary Layer approach with a combination of wind and currents-based models for the estimation of the gas transfer velocities. The two bays were strong sources of both CH₄ and N₂O with no significant differences in the degree of saturation of both gases between them during all measurement campaigns. Both CH₄ and N₂O concentrations had strong temporal but minimal spatial variability in both bays. During the seven seasons, CH₄ varied between 500% and 4000% saturation while N₂O varied between 128 and 255% in the two bays. Average seasonal CH₄ fluxes for the two bays varied between 0.5 ± 0.2 and 6.0 ± 1.5 mg CH₄/(m²·day) while N₂O varied between 0.4 ± 0.1 and 1.6 ± 0.6 mg N₂O/(m²·day). Weighted emissions (t CO₂-e) were 63%-90% N₂O dominated implying that a reduction in N₂O inputs and/or nitrogen availability in the bays may significantly reduce the bays' greenhouse gas (GHG) budget. Emissions data for tropical and subtropical systems is still scarce. This work found subtropical bays to be significant aquatic sources of both CH₄ and N₂O and puts the estimated fluxes into the global context with measurements done from other climatic regions.     

Methane and nitrous oxide fluxes from four tundra ecotopes in Ny-Ålesund of the High Arctic

During the summers of 2008 and 2009, net methane（CH4） and nitrous oxide（N2O） fluxes were investigated from 4 tundra ecotopes： normal lowland tundra（LT）, bird sanctuary tundra（BT）, the tundra in an abandoned coal mine（CT） and the tundra in scientific bases（ST） in Ny-Alesund of the High Arctic. Tundra soils in CT（184.5 ± 40.0 μg CH4/（m2·hr）） and ST（367.6 ± 92.3 μg CH4/（m2·hr）） showed high CH4 emissions due to the effects of human activities, whereas high CH4 uptake or low emission occurred in the soils of LT and BT.The lowland tundra soils（mean,-4.4-4.3 μg N2O/（m2·hr）） were weak N2 O sources and even sinks. Bird activity increased N2 O emissions from BT with the mean flux of7.9 μg N2O/（m2·hr）. The mean N2 O fluxes from CT（45.4 ± 10.2 μg N2O/（m2·hr）） and ST（78.8 ± 18.5 μg N2O/（m2·hr）） were one order of magnitude higher than those from LT and BT, indicating that human activities significantly increased N2 O emissions from tundra soils. Soil total carbon and water regime were important factors affecting CH4 fluxes from tundra soils. The N2 O fluxes showed a significant positive correlation with ammonia nitrogen（NH4＋-N） contents（r = 0.66, p 〈 0.001） at all the observation sites, indicating that ammonia nitrogen（NH4＋-N） content acted as a strong predictor for N2 O emissions from tundra soils. The CH4 and N2O fluxes did not correspond to the temperature variations of soil at 0-15 cm depths.Overall our results implied that human activities might have greater effects on soil CH4 and N2O emissions than current climate warming in Ny-Alesund, High Arctic.     

模拟酸雨对福州平原水稻田温室气体排放的影响

农田生态系统是温室气体的重要排放源,研究酸雨对水稻田温室气体排放及其综合增温潜势的影响,对我国酸雨背景下农田生态系统固碳减排具有重要的现实意义.本文以福州平原水稻田为研究区,通过模拟酸雨探讨其对水稻田CO_2、CH_4和N_2O排放通量及其综合增温潜势的影响.结果表明:模拟酸雨并未显著改变早、晚稻田CO_2、CH_4和N_2O排放的季节变化规律,但降低了其排放通量.与对照组相比,pH=4.5酸雨作用下,早稻田CO_2、CH_4和N_2O平均排放通量依次降低11.54%、133.33%和22.22%,晚稻田CO_2和N_2O平均排放通量依次降低39.53%、156.00%,而CH_4平均排放通量与对照组差异不显著;pH=3.5酸雨作用下,早稻田CO_2、CH_4和N_2O平均排放通量分别降低10.82%、75.00%、54.00%,晚稻田平均排放通量分别降低17.32%、20.00%和197.67%.综合增温潜势表明,CO_2的增温潜势显著高于CH_4和N_2O,是稻田生态系统中温室效应的主要温室气体,在pH=4.5和pH=3.5的酸雨作用下,早、晚稻田生态系统温室气体综合增温潜势均降低.     

Methane and nitrous oxide emissions from a subtropical coastal embayment (Moreton Bay,Australia)

Surface water methane (CH₄) and nitrous oxide (N₂O) concentrations and fluxes were investigated in two subtropical coastal embayments (Bramble Bay and Deception Bay, which are part of the greater Moreton Bay, Australia). Measurements were done at 23 stations in seven campaigns covering different seasons during 2010–2012. Water–air fluxes were estimated using the Thin Boundary Layer approach with a combination of wind and currents-based models for the estimation of the gas transfer velocities. The two bays were strong sources of both CH₄ and N₂O with no significant differences in the degree of saturation of both gases between them during all measurement campaigns. Both CH₄ and N₂O concentrations had strong temporal but minimal spatial variability in both bays. During the seven seasons, CH₄ varied between 500% and 4000% saturation while N₂O varied between 128 and 255% in the two bays. Average seasonal CH₄ fluxes for the two bays varied between 0.5 ± 0.2 and 6.0 ± 1.5 mg CH₄/(m²·day) while N₂O varied between 0.4 ± 0.1 and 1.6 ± 0.6 mg N₂O/(m²·day). Weighted emissions (t CO₂-e) were 63%–90% N₂O dominated implying that a reduction in N₂O inputs and/or nitrogen availability in the bays may significantly reduce the bays' greenhouse gas (GHG) budget. Emissions data for tropical and subtropical systems is still scarce. This work found subtropical bays to be significant aquatic sources of both CH₄ and N₂O and puts the estimated fluxes into the global context with measurements done from other climatic regions.     

盐碱区不同开发年限水田温室气体排放规律及影响因素

以吉林省前郭盐碱水田区为研究对象,采用野外采样和小区试验相结合的方法,监测水稻生长期土壤温室气体(CH4和N2O)排放、土壤p H和土壤有机碳(SOC)变化,分析水田温室气体排放规律及其影响因素.结果表明,水田N2O排放季节变化特征明显并呈现3个峰值,肥料的施入提供了更多的反应底物,对水田N2O的排放量影响显著.在淹水条件下,N2O的主要来源于反硝化过程,而排水后,硝化作用则占据了主导地位.CH4排放呈现单峰,在水稻生长旺盛的分蘖期,稻田较深水层以还原环境为主,为产生CH4的微生物提供了适宜的条件,进而导致CH4排放呈高峰值;土壤p H对N2O和CH4排放的影响不明显,但土壤SOC含量与CH4的排放规律呈现显著正相关.     

卫河新乡市区段春季溶解CH4与N2O浓度特征

对卫河新乡市区段春季CH_4与N_2O浓度进行调查分析,初步探讨了城市河流中典型温室气体的溶存量空间变化及其影响因素.结果表明,受到水中污染物质浓度及人类活动影响,春季卫河表层水中CH_4与N_2O浓度处于超饱和状态,饱和度分别为147.59~2 667.85和4.06~188.25.影响市区内N_2O浓度的主要环境因素为NH~+_4-N(P0.01),而新区污水处理厂排水输入显著提高了N_2O的溶存量,说明污染物类型影响温室气体的产生和积累,NH~+_4-N的硝化过程是城市河流N_2O产生的主要来源.逐步回归分析表明CH_4浓度是NH~+_4-N浓度与水温的相关函数,其中CH_4浓度与NH~+_4-N极显著相关(R2=0.70,P0.01),说明春季卫河中NH~+_4-N浓度是影响卫河春季CH_4溶存的关键因素.此外研究结果显示在NO~-_3-N浓度较低并且NH~+_4-N浓度高时水中CH_4与N_2O浓度具有显著正相关关系,表明有效态氮浓度差异影响CH_4与N_2O产生过程的耦合机制.     

Biochar addition to agricultural soil increased CH4 uptake and water holding capacity – Results from a short-term pilot field study

Biochar addition to agricultural soil has been suggested to mitigate climate change through increased biogenic carbon storage and reduction of greenhouse gas emissions. We measured the fluxes of N₂O, CO₂, and CH₄ after adding 9 t ha^?1 biochar on an agricultural soil in Southern Finland in May 2009. We conducted these measurements twice a week for 1.5 months, between sowing and canopy closure, to capture the period of highest N₂O emissions, where the potential for mitigation would also be highest. Biochar addition increased CH₄ uptake (96% increase in the average cumulative CH₄ uptake), but no statistically significant differences were observed in the CO₂ and N₂O emissions between the biochar amended and control plots. Added biochar increased soil water holding capacity by 11%. Further studies are needed to clarify whether this may help balance fluctuations in water availability to plants in the future climate with more frequent drought periods.     

北京上甸子站气相色谱法大气CH4和CO在线观测方法研究

参照瓦里关全球大气本底站气相色谱在线观测系统的设计,通过系统调试、测试和参数优化,于2009年在北京上甸子区域大气本底站建立了高精度气相色谱法大气CH4和CO在线观测系统.该系统对CH4和CO的测量精度分别优于0.03%和0.45%,达到世界气象组织全球大气观测计划(WMO/GAW)的质量目标.研究建立了与该系统配套的标气选取方法及运行序列:选取可基本涵盖该站大气CH4和CO浓度范围的2瓶标气作为工作标气,其中CH4浓度分别为2 007.1×10-9、1 809.5×10-9(摩尔分数,下同),CO浓度分别为405.6×10-9、123.8×10-9,在高低浓度工作标气之间穿插分析3次大气样品,能够保证测量的准确度(观测浓度的标准偏差CH4<1.7×10-9、CO<1×10-9),同时可最大程度地节省工作标气.该方法已应用于华北地区本底大气CH4和CO的高精度连续观测.     

Atmospheric sulfur hexafluoride in-situ measurements at the Shangdianzi regional background station in China

We present in-situ measurements of atmospheric sulfur hexafluoride（SF6） conducted by an automated gas chromatograph–electron capture detector system and a gas chromatography/mass spectrometry system at a regional background site, Shangdianzi,in China, from June 2009 to May 2011, using the System for Observation of Greenhouse gases in Europe and Asia and Advanced Global Atmospheric Gases Experiment（AGAGE）techniques. The mean background and polluted mixing ratios for SF6 during the study period were 7.22 × 10-12（mol/mol, hereinafter） and 8.66 × 10-12, respectively. The averaged SF6 background mixing ratios at Shangdianzi were consistent with those obtained at other AGAGE stations located at similar latitudes（Trinidad Head and Mace Head）, but larger than AGAGE stations in the Southern Hemisphere（Cape Grim and Cape Matatula）. SF6 background mixing ratios increased rapidly during our study period, with a positive growth rate at 0.30 × 10-12year-1. The peak to peak amplitude of the seasonal cycle for SF6 background conditions was 0.07 × 10-12, while the seasonal fluctuation of polluted conditions was 2.16 × 10-12. During the study period, peak values of SF6 mixing ratios occurred in autumn when local surface horizontal winds originated from W/WSW/SW/SWS/S sectors, while lower levels of SF6 mixing ratios appeared as winds originated from N/NNE/NE/ENE/E sectors.     

猪粪化肥配施对双季稻田CH4和N2O排放及其全球增温潜势的影响

以湖南典型红壤双季稻田系统为研究对象,采用静态箱-气相色谱法研究了水稻生长季基肥配施猪粪条件下CH4和N2O的排放特征,并估算了排放的CH4和N2O的全球增温潜势(GWP).结果表明,与施用化肥处理相比,猪粪化肥配施对稻田CH4和N2O排放的季节变化模式无明显影响,但影响其排放量大小.两个稻季,猪粪替代50%化学氮肥处理(1/2N+PM)CH4累积排放量较不施氮肥处理(0N)、50%化学氮肥处理(1/2N)、100%化学氮肥处理(N)分别提高54.83%、33.85%和43.30%(P<0.05);1/2N+PM处理N2O累积排放量较N处理显著降低67.50%,较0N处理、1/2N处理分别提高129.43%、119.23%(P<0.05).水稻生长季CH4是GWP的主要贡献者,占CH4和N2O综合GWP的99%以上.1/2N+PM处理的GWP显著高于其他处理(P<0.05),且1/2N+PM处理单位产量GWP最高,较N处理、1/2N处理、0N处理分别提高58.21%、26.82%、20.63%.因此,双季稻田猪粪替代部分化学氮肥较全部施用化学氮肥增加了双季稻田CH4和N2O排放的综合温室效应,其对温室气体排放的影响需在区域温室气体排放清单中加以考虑.     

不同干扰强度下三江平原湿地土壤温室气体排放对冻融作用的响应

为评估季节性冻融作用对不同干扰强度湿地温室气体产生机制的影响,采用静态箱/气相色谱法,原位观测三江平原洪河国家自然保护区内未受干扰的常年积水的小叶章湿地(undisturbed Deyeuxia angustifolia wetland,UDAW)、保护区外受人类活动干扰导致湿地含水量减少的季节性积水的小叶章湿地(disturbed Deyeuxia angustifolia wetland,DDAW)以及由小叶章湿地开垦10年以上的水稻田(rice paddy,RP)的温室气体排放通量,分析季节性冻融作用对3种湿地温室气体排放的影响特征.结果表明:3种湿地在冻融期均有CO₂和CH₄排放,且在春季冻融初期CO₂和CH₄均出现短期的高排放现象,随着冻融温度升高,温室气体排放通量均逐渐增加.其中,CO₂排放通量表现为UDAW > DDAW > RP,CH₄排放通量却表现为DDAW > RP > UDAW;DDAW的CH₄排放速率与冻融温度的相关性最高(P < 0.01,R2=0.647 5),UDAW中二者的相关性最低(P < 0.01,R2=0.424 7).相关性分析显示,DDAW和RP土壤中CO₂与CH₄的排放通量均呈正相关(P均小于0.01,R2分别为0.749 1、0.574 4),而UDAW土壤中CO₂与CH₄的排放通量表现为弱相关(P < 0.05,R2=0.303 8),可见冻融温度会影响CO₂和CH₄的排放通量.季节性冻融作用影响了3种湿地土壤N₂O的排放通量,秋季冻融期UDAW和DDAW表现为N₂O的汇,而在春季冻融期3种湿地均表现为N₂O的源,表明不同干扰湿地N₂O的排放通量对冻融作用的响应不同,但均随土壤温度的升高其排放通量不断增加.研究显示,三江平原的冻融作用降低了湿地温室气体排放,干扰强度越大,冻融作用影响越小,且秋季冻融作用大于春季.      

稻田不同种类有机肥施用对后季麦田N2O排放的影响

以稻麦轮作系统为对象,研究水稻生长季基肥施用不同有机物料对后季麦田N₂O排放及年轮作系统CH₄和N₂O综合温室效应的影响.结果表明:与施用化肥(化肥处理)相比,施用菜饼加化肥(菜饼处理)对后季麦田N₂O排放量无影响;施用小麦秸秆加化肥(小麦秸秆处理)导致后季麦田的N₂O排放量减少15%;施用牛厩肥加化肥(牛厩肥处理)和猪厩肥加化肥(猪厩肥处理)分别增加29%和16%.就稻麦年轮作生长季总体而言,菜饼、牛厩肥和猪厩肥处理稻麦生长季N₂O排放总量较化肥处理分别增加6%、17%和7%,然而,小麦秸秆处理N₂O排放总量减少16%.20a或500a时间尺度上各处理稻田CH₄排放和该轮作周期水稻和小麦生长季N₂O排放的总GWP值由大到小的顺序分别为:菜饼处理>小麦秸秆处理>牛厩肥处理>猪厩肥处理>化肥处理或菜饼处理>牛厩肥处理>猪厩肥处理>小麦秸秆处理>化肥处理.单位产量的GWP以作物残体处理最高,农家肥其次,化肥处理最低.因此,稻田基施不同种类有机物料都相应地增加稻麦轮作系统CH₄和N₂O排放的综合温室效应.     

南极菲尔德斯半岛植被土壤N2O排放特征

应用密闭箱法首次测定了南极菲尔德斯半岛苔藓、地衣植被土壤N2O的排放通量,并估算了该半岛植被区土壤在夏季2个月内N₂O的排放总量.结果表明:在晴天和雨天,苔藓土壤N₂O的排放通量与温度有较好的响应关系,呈现单峰型变化趋势;但在雪天,与温度的变化不一致;苔藓、地衣这2种不同的植被土壤N2O排放通量日变化基本一致;温度是影响苔藓土壤N2O的排放通量季节变化的主要因子,同时还受降水的影响,干湿交替有利于N2O的排放;苔藓土壤N₂O的排放总量为3.7152kg;地衣土壤N₂O的排放总量为2.5344kg.由此可见,南极菲尔德斯半岛苔藓、地衣植被土壤N₂O排放量虽然很小,但仍起着大气N₂O源的作用.     

秸秆与化肥减量配施对菜地土壤温室气体排放的影响

采用静态箱/气相色谱法,2016年11月至2017年9月通过田间原位试验,设置了无物料还田(CK)、常规化肥(F)、秸秆还田配施100%化肥(100FS)、秸秆还田配施70%化肥(70FS)、秸秆还田配施60%化肥(60FS)、秸秆还田配施50%化肥(50FS),对比分析了在化肥减量的基础上,配施秸秆处理的菜地(莴笋-卷心菜-辣椒轮作)土壤CO_2、CH_4、N_2O动态变化特征及温室效应,研究秸秆与化肥减量配施对菜地温室气体排放的影响.结果表明,土壤CO_2、CH_4、N_2O排放具有一定的季节变化规律,排放高峰主要集中在4~8月,且在施肥灌水后均会出现气体的排放峰.秸秆与化肥配施较常规施肥(F)处理提高了土壤N_2O排放量,累积排放量及其排放系数,其中100FS处理的效果最为明显,辣椒季的累积排放通量明显高于莴笋季和卷心菜季,高达60.76 kg·hm~(-2)(P0.05),N_2O的排放系数(以N_2O-N/N计)为0.138 kg·kg-1,而秸秆与化肥减量配施较100FS处理可以降低氮肥的N_2O排放系数.与对照CK和F处理相比,70FS处理降低了土壤CO_2排放量和累积排放量,分别为55.28~1 831.62 mg·(m2·h)-1和7 502.13~25 988.55 kg·hm~(-2),而其他秸秆与化肥配施处理均增加了CO_2累积排放通量,尤其是60FS和50FS处理.对土壤CH_4排放而言,辣椒季的排放波动较大,除CK外,各处理的土壤CH_4累积排放量多为负值,表现为大气中CH_4汇;秸秆与化肥减量30%~50%配施处理均降低了辣椒季的土壤CH_4排放量和累积排放通量,而100FS处理提高了CH_4排放量和累积排放通量.与CK和F处理相比,除70FS外,100FS、60FS和50FS均显著提高了GWP.总体上,从温室气体排放角度,在常规化肥施用的基础上减量30%再与秸秆配施可以降低土壤CO_2和CH_4排放,缓解温室气体的增温潜势,而对土壤N_2O减排效果不显著.     

Effect of C/N ratio, aeration rate and moisture content on ammonia and greenhouse gas emission during the composting

Gaseous emission (N₂O, CH₄ and NH₃) from composting can be an important source of anthropogenic greenhouse gas and air pollution. A laboratory scale orthogonal experiment was conducted to estimate the effects of C/N ratio, aeration rate and initial moisture content on gaseous emission during the composting of pig faeces from Chinese Ganqinfen system. The results showed that about 23.9% to 45.6% of total organic carbon (TOC) was lost in the form of CO₂ and 0.8% to 7.5% of TOC emitted as CH₄. Most of the nitrogen was lost in the form of NH₃, which account for 9.6% to 32.4% of initial nitrogen. N₂O was also an important way of nitrogen losses and 1.5% to 7.3% of initial total nitrogen was lost as it. Statistic analysis showed that the aeration rate is the most important factor which could affect the NH₃ (p = 0.0189), CH₄ (p = 0.0113) and N₂O (p = 0.0493) emissions significantly. Higher aeration rates reduce the CH₄ emission but increase the NH₃ and N₂O losses. C/N ratio could affect the NH₃ (p = 0.0442) and CH₄ (p = 0.0246) emissions significantly, but not the N₂O. Lower C/N ratio caused higher NH₃ and CH₄ emissions. The initial moisture content can not influence the gaseous emission significantly. Most treatments were matured after 37 days, except a trial with high moisture content and a low C/N ratio.     

优化施肥模式对我国热带地区水稻-豇豆轮作系统N2O和CH4排放的影响

选择海南典型的水稻-豇豆轮作系统进行氧化亚氮(N_2O)和甲烷(CH_4)排放的原位监测,探究不同施肥模式下该系统土壤温室气体排放特征.试验设当地常规施肥对照(CON)、优化施肥量(OPT)、有机无机配施(ORG)、缓控肥替代优化(SCOPT)及不施氮对照(CK)共5个处理,采用静态箱-气相色谱法监测整个种植季土壤N_2O和CH_4排放,并估算增温潜势(GWP)和温室气体排放强度(GHGI).结果表明,各处理水稻季N_2O累积排放量为0. 19～1. 37 kg·hm~(-2),相较于CON处理,优化施肥处理N_2O减排50%～86%;豇豆季N_2O累积排放量为1. 29～3. 55 kg·hm~(-2),除ORG增加14%,其他处理减排16%～59%.各处理水稻季CH_4累积排放量为4. 67～14. 23 kg·hm~(-2),CK、OPT和ORG处理分别较CON增加116%、22%和102%,而SCOPT减少了29%;豇豆季CH_4累积排放量为0. 03～0. 26 kg·hm~(-2),期间出现CH_4吸收.比较两个作物季和休闲期对农田土壤直接排放的温室气体GWP的贡献率,豇豆季在CH_4排放极低的情况下,仍有44. 7%～54. 5%的占比;两种温室气体比较中,N_2O对GWP的贡献率为66. 7%～77. 2%. SCOPT处理的GWP和两季作物GHGI均显著低于CON处理.3个优化施肥处理中,SCOPT的增产减排效果最显著,为最优的施肥方案.