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1.
采用漂浮通量箱法和扩散模型法同步地观测了模拟内陆水体在不同条件下的CH4和N2O的水-气交换通量,旨在比较两类方法取得结果的异同。结果显示:这两类方法所测得的绝大多数CH4排放通量都与水中溶解氧呈显著线性负相关(显著性系数P0.001)。同时N2O排放通量与表层水温及水中铵态氮、硝态氮、溶解碳和溶解氧的关系可用包含所有上述水环境因素的Arrhenius动力学方程来表达,这些因素可以共同解释86%~90%的N2O通量变化(P0.0001),且不同方法测定的N2O通量的表观活化能和对表层水温的敏感系数分别介于47~59 kJ mol-1和1.92~2.27之间;扩散模型法所获得的CH4和N2O通量分别是箱法测定值的13%~175%和15%~240%,差异程度因模型而异;不同模型取得通量间相差20%~1200%,平均相差2.3倍。上述结果表明:仅用一种模型方法来取得CH4或N2O排放通量易形成较大偏差;不同扩散模型法和箱法测定的通量在反映CH4和N2O排放的内在规律方面具有一致性,但它们对真实气体通量的测量是否都存在不同程度的系统误差,尚需进一步研究。 相似文献
2.
半干旱草原温室气体排放/吸收与环境因子的关系研究 总被引:13,自引:3,他引:10
静态箱一气相色谱法对内蒙古半干旱草原连续两年的实验观测研究结果表明,内蒙古草原是大气CO2和N2O的排放源,而是CH4的汇.在植物生长不同季节,草原生态系统排放/吸收温室气体CO2,CH4和N2O的日变化形式各有不同,其中在植物生长旺季日变化形式最具特征.3种温室气体的季节排放/吸收高峰主要出现在土壤湿度较大的春融和降雨较为集中时期.所有草原植物生长季节CO2净排放日变化形式均为白天出现排放低值,夜间出现排放高值.较高的温度有利于CO2排放,地上生物量决定着光合吸收CO2量值的高低.影响半干旱草原吸收CH4和排放N2O日变化形式的关键是土壤含水量和供氧状况,日温变化则主要影响日变化强度.吸收CH4和排放N2O的季节变化与土壤湿度季节变化分别呈线性反、正相关,相关系数均在0.4~0.6之间.自由放牧使CO2、N2O和CH4交换速率日较差降低,同时使N2O和CH4年度排放/吸收量减少和CO2年度排放量增加. 相似文献
3.
半干旱草原温室气体排放/吸收与环境因子的关系研究 总被引:7,自引:0,他引:7
静态箱—气相色谱法对内蒙古半干旱草原连续两年的实验观测研究结果表明,内蒙古草原是大气CO2和N2O的排放源,和CH4的汇。在植物生长不同季节,草原生态系统排放/吸收温室气体CO2、CH4和N2O的日变化形式各有不同,其中在植物生长旺季日变化形式最具特征。三种温室气体的季节排放/吸收高峰主要出现在土壤湿度较大的春融期和降雨较为集中时期。对所有草原植物生长季节,CO2净排放日变化形式均为白天出现排放低值,夜间出现排放高值。较高的温度有利于CO2排放,地上生物量决定着光合吸收CO2量值的高低。影响半干旱草原吸收CH4和排放N2O日变化形式的关键是土壤台水量和供氧状况,日温变化则主要影响日变化强度。吸收CH4和排放N2O的季节变化与土壤湿度季节变化分别呈线性反、正相关,相关系数均在0.4-0.6之间。自由放牧使CO2、N2O和CH4交换速率日较差降低,同时使N2O和CH4年度排放/吸收量减少和CO2年度排放量增加。 相似文献
4.
利用静态箱法于2011年结实期和2012年开花期与结实期分别对不同人类活动(自由放牧和刈割)影响下的呼伦贝尔草甸草原及相应的封育草原的CH4通量和植物土壤系统呼吸作用排放的CO2通量进行野外定位观测研究。结果表明:呼伦贝尔草甸草原(放牧和刈割及其对应的封育样地)均表现为CH4的汇,3个观测时期汇强的变化范围为:-23.98±6.40~-95.96±28.57μg Cm-2 h-1。呼伦贝尔草甸草原CH4通量的日变化对温度的响应较为复杂。不同时期呼伦贝尔草甸草原的植物土壤系统呼吸速率的日变化存在差异,水分和温度的共同影响造成2012年结实期日均CO2排放量低于2011年结实期。放牧对呼伦贝尔草甸草原CH4吸收通量的日变化模式的影响较小,但在2011年结实期和2012年开花期促进了CH4日均通量(促进幅度12.05%~93.35%),2012年结实期放牧降低了CH4日均通量(降低幅度23.32%~30.43%);刈割降低CH4吸收日均通量11.55%~60.62%。呼伦贝尔草甸草原日均累计碳排放量中CH4所占比例为0.35%~2.62%,而放牧和刈割行为对呼伦贝尔草甸草原的日均累计碳排放的影响结果在不同物候期以及不同植被群落类型均有不同。 相似文献
5.
种植不同作物对农田N2O和CH4排放的影响及其驱动因子 总被引:3,自引:0,他引:3
以种植玉米(Zea mays)、大豆(Glycine max)和水稻(Oryza sativa)的农田生态系统为研究对象,于2003年6~10月系统观测了N2O和CH4的排放、土壤温度和湿度以及相关的生物学因子。玉米和水稻分别施化肥氮300 kg.hm-2,大豆未施氮肥。研究结果表明,作物类型对农田N2O和CH4排放具有显著的影响。土壤-玉米系统、土壤-大豆系统和土壤-水稻系统的N2O季节性平均排放通量分别为620.5±57.6、338.0±7.5和238.8±13.6μg.m-2.h-1(N2O)。种植作物促进了农田生态系统的N2O排放,玉米地土壤和裸地土壤的N2O平均排放通量分别为364.2±11.7和163.7±10.5μg.m-2.h-1(N2O)。土壤-玉米系统、土壤-水稻系统、玉米地土壤和裸地土壤N2O排放受土壤温度的影响,与土壤湿度无显著统计相关,但受土壤温度和水分的综合影响。土壤-大豆系统N2O排放随作物绿叶干重的增加而指数增加,与土壤温度和水分条件无统计相关,由大豆作物自身氮代谢所产生的N2O-N季节总量约为6.2 kg.hm-2(N)。土壤-水稻系统CH4平均排放通量为1.7±0.1 mg.m-2.h-1(CH4),烤田抑制了稻田CH4的排放。烤田前影响稻田CH4排放的主要因素是水稻生物量,烤田后的浅水灌溉及湿润灌溉阶段的CH4排放与土壤温度和水稻生物量无关。本研究未观测到旱作农田有吸收CH4的现象。 相似文献
6.
小麦秸秆还田量对晋南地区裸地土壤—大气间甲烷、二氧化碳、氧化亚氮和一氧化氮交换的影响 总被引:11,自引:0,他引:11
采用静态暗箱采样—气相色谱/化学发光分析相结合的方法,对晋南地区盐碱地不同小麦秸秆还田量裸地土壤夏、秋季(2008年6~10月)的甲烷(CH4)、二氧化碳(CO2)、氧化亚氮(N2O)和一氧化氮(NO)交换通量进行了原位观测。结果表明:观测期内,秸秆全还田(FS)、秸秆一半还田(HS)和秸秆不还田(NS)处理土壤—大气间CH4、CO2、N2O和NO平均交换通量分别为-0.8±2.7、-1.4±2.3、-6.5±1.8μg(C).m-2.h-1(CH4),267.1±23.1、212.0±17.8、188.5±13.6mg(C).m-2.h-1(CO2),20.7±3.0、16.3±2.3、14.7±1.7μg(N).m-2.h-1(N2O),3.9±0.5、3.4±0.5、3.0±0.4μg(N).m-2.h-1(NO)。交换通量表现出明显的季节变化趋势,灌溉、降雨和温度变化是影响该趋势的主要因素。相对于NS处理,FS和HS处理降低了累积CH4吸收量(66%和59%),增加了累积CO2(42%和12%)、N2O(41%和9%)和NO(30%和13%)排放量,因此,秸秆还田促进了农田土壤总的温室气体排放。计算得到FS和HS处理小麦秸秆的CO2、N2O、NO排放系数分别为73.4%±1.6%和43.3%±1.0%(CO2)、0.37%±0.01%和0.17%±0.00%(N2O)、0.06%±0.00%和0.05%±0.00%(NO),FS处理的排放系数显著高于HS处理,且均低于同一实验地种植玉米、施肥农田的小麦秸秆排放系数(N2O和NO排放系数分别为2.32%和0.42%)。可见,在采用排放因子方法估算还田秸秆CO2、N2O和NO排放量时,应考虑秸秆还田量、农作物种植和施肥因素的影响。 相似文献
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8.
华北平原冬麦田土壤CH4的吸收特征研究 总被引:9,自引:0,他引:9
利用静态箱/气相色谱(GC)法,对华北平原冬小麦拔节—成熟期间麦田土壤CH4气体通量进行了测定,得出华北平原典型冬麦田土壤是大气CH4的弱吸收汇。试验期间土壤CH4通量存在明显的季节变化和日变化,麦田拔节—成熟期间土壤CH4通量日平均值为-18.3μg.m-2.h-1,波动范围为-4.3~-24.4μg.m-2.h-1;在土壤CH4通量的日变化中,观测到麦田土壤在午间和夜间都有一个吸收峰,峰值出现的时间因生育期不同而有所不同。试验期间CH4通量日平均值与土壤温度关系不明显,而与土壤水分呈负相关(α=0.01);日变化中土壤CH4通量与地表温度的相关性较差,而与5 cm地温相关密切。麦田拔节—成熟期间土壤CH4通量日平均值随NH4 -N施用量的增加呈递减规律,农田秸秆还田后不利于土壤对CH4的吸收。 相似文献
9.
内蒙古草原温室气体排放日变化规律研究 总被引:11,自引:0,他引:11
采用静态值-气相色谱法研究内蒙古草原温室气体N2O、CO2、CH4与大气交换的日变化规律。CO2日排放变化形式基本相同,和大气交换的总结果是向大气排放,影响草原N2O排放日变化形式的关键是土壤含水量和表层土壤理化特性,日温变化主要影响其日变化强度;影响草原CH4日变化形式的关键因子是土壤水分和供氧状况,而温度和植物的生长状况则影响吸收强度,利用内蒙古草原温室气候排放相对固定的日变化形式,可以对相同生产季内每周1次的观测结果进行矫正。 相似文献
10.
1990年7—9月,在浙江临安(30°14'N,119°42'E),利用微气象学(梯度廓线)法及箱式技术对水稻田CH4排放通量进行了同步观测,取得了中稻整个生长期内的CH4排放资料。文章仅对箱式技术的观测结果作了介绍与分析。观测发现在整个灌溉期内,稻田CH4释放率为3.67—16.14 mg/m2·h,均值为10.58 mg/m2·h。CH4排放的季节变化明显,日变化也同样很明显。另外还发现,CH4排放通量与水(地)温及其他气象因素,如强风、阴雨等有关。与梯度廓线法的观测结果不同,箱式观测到的CH4排放通 相似文献
11.
本研究首次以我国内蒙古典型草原生态系统为研究对象,以密闭箱法对土壤-植物系统与大气间N2O和CH4气体交换进行了原位观测研究,通过结合实验室模拟实验研究表明,土壤含水量和温度对草原土壤-植物系统温室气体(N2O和CH4)排放通量有着重要的影响。在一定范围内,土壤含水量增加促进草原生态系统N2O排放和CH4吸收作用。温度升高促进草原生态系统N2O排放,但对CH4吸收的影响作用不明显。 相似文献
12.
箱法和微气象学方法是当前用以现场测量陆地生态系统温室气体排放的主要方法。本文较系统地介绍了获得较广泛应用的箱法和主要微气象学法,如涡度相关法、空气动力学法、能量平衡法和质量平衡法等。对各类方法的适用性及其科学局限性进行了比较、简评。最后给出了“内蒙古半干旱草原土壤-植被-大气相互作用”(IMGRASS)项目中开展温室气体排放(吸收)现场观测方法的选择。 相似文献
13.
Chuanjie YANG Guang LI Lijuan YAN Weiwei MA Jiangqi WU Yan TAN Shuainan LIU Shikang ZHANG 《大气科学进展》2022,39(8):1360-1374
Methane (CH4) is an important greenhouse gas second only to CO2 in terms of its greenhouse effect. Vegetation plays an important role in controlling soil CH4 fluxes, but the spatial variability of soil CH4 fluxes during vegetation restoration in Loess Hilly Region (LHR) is not fully understood. The effects of different plant community types [Medicago sativa grassland (MS); Xanthoceras sorbifolium forestland (XS); Caragana korshinskii bushland (CK); Hippophae rhamnoides shrubland (HR); and Stipa bungeana grassland (SB)] on soil CH4 flux in LHR were studied via the static chamber technique. The results showed that the five plant community types were sinks of soil CH4 in LHR, the plant community type significantly affected the soil CH4 flux, and the average CH4 uptake from high to low was in SB, HR, CK, MS, and XS. During the whole study period, the soil CH4 flux showed similar interannual variation. The maximum absorption of soil CH4 appeared in the growing season, while the minimum appeared in winter. Soil CH4 uptake was positively correlated with soil temperature and soil moisture. Soil temperature and moisture are important controlling factors for the temporal variability of soil CH4 flux. In LHR, the Stipa bungeana grassland is the more suitable plant community type for reducing soil CH4 emissions. In the process of vegetation restoration in LHR, the soil CH4 absorption potential of different plant community types should be considered, ecological benefits should be taken into account, and vegetation more suitable for mitigating the greenhouse effect should be selected. 相似文献
14.
Three-year Variations of Water, Energy and CO_2 Fluxes of Cropland and Degraded Grassland Surfaces in a Semi-arid Area of Northeastern China 总被引:1,自引:0,他引:1
Based on 3 years (2003-05) of the eddy covariance (EC) observations on degraded grassland and cropland surfaces in a semi-arid area of Tongyu (44°25′N, 122°52′E, 184 m a.s.1.), Northeast China, seasonal and annual variations of water, energy and CO2 fluxes have been investigated. The soil moisture in the thin soil layer (at 0.05, 0.10 and 0.20 m) clearly indicates the pronounced annual wet-dry cycle; the annual cycle is divided into the wet (growing season) and dry seasons (non-growing season). During the growing season (from May to September), the sensible and latent heat fluxes showed a linear dependence on the global solar radiation. However, in the non-growing season, the latent heat flux was always less than 50 W m^-2, while the available energy was dissipated as sensible, rather than latent heat flux. During the growing season in 2003-05, the daily average sensible and latent heat fluxes were larger on the cropland surface than on the degraded grassland surface. The cropland ecosystem absorbed more CO2 than the degraded grassland ecosystem in the growing season in 2003-05. The total evapotranspiration on the cropland was more than the total precipitation, while the total evapotranspiration on the degraded grassland was almost the same as the total annual precipitation in the growing season. The soil moisture had a good correlation with the rainfall in the growing season. Precipitation in the growing season is an important factor on the water and carbon budget in the semi-arid area. 相似文献
15.
Annett Wolf Eleanor Blyth Richard Harding Daniela Jacob Elke Keup-Thiel Holger Goettel Terry Callaghan 《Climatic change》2008,87(1-2):75-89
We tested the sensitivity of a dynamic ecosystem model (LPJ-GUESS) to the representation of soil moisture and soil temperature
and to uncertainties in the prediction of precipitation and air temperature. We linked the ecosystem model with an advanced
hydrological model (JULES) and used its soil moisture and soil temperature as input into the ecosystem model. We analysed
these sensitivities along a latitudinal gradient in northern Russia. Differences in soil temperature and soil moisture had
only little influence on the vegetation carbon fluxes, whereas the soil carbon fluxes were very sensitive to the JULES soil
estimations. The sensitivity changed with latitude, showing stronger influence in the more northern grid cell. The sensitivity
of modelled responses of both soil carbon fluxes and vegetation carbon fluxes to uncertainties in soil temperature were high,
as both soil and vegetation carbon fluxes were strongly impacted. In contrast, uncertainties in the estimation of the amount
of precipitation had little influence on the soil or vegetation carbon fluxes. The high sensitivity of soil respiration to
soil temperature and moisture suggests that we should strive for a better understanding and representation of soil processes
in ecosystem models to improve the reliability of predictions of future ecosystem changes. 相似文献
16.
Yue-Lin Li Guo-Yi Zhou De-Qiang Zhang Katherine Owen Wenigmann Dennis Otieno John Tenhunen Qian-Mei Zhang Jun-Hua Yan 《Asia-Pacific Journal of Atmospheric Sciences》2012,48(1):1-10
CO2 fluxes were measured continuously for three years (2003?C2005) using the eddy covariance technique for the canopy layer with a height of 27 m above the ground in a dominant subtropical evergreen forest in Dinghushan, South China. By applying gapfilling methods, we quantified the different components of the carbon fluxes (net ecosystem exchange (NEE)), gross primary production (GPP) and ecosystem respiration (Reco) in order to assess the effects of meteorological variables on these fluxes and the atmospherecanopy interactions on the forest carbon cycle. Our results showed that monthly average daily maximum net CO2 exchange of the whole ecosystem varied from ?3.79 to ?14.24 ??mol m?2 s?1 and was linearly related to photosynthetic active radiation. The Dinghushan forest acted as a net carbon sink of ?488 g C m?2 y?1, with a GPP of 1448 g Cm?2 y?1, and a Reco of 961 g C m?2 y?1. Using a carboxylase-based model, we compared the predicted fluxes of CO2 with measurements. GPP was modelled as 1443 g C m?2 y?1, and the model inversion results helped to explain ca. 90% of temporal variability of the measured ecosystem fluxes. Contribution of CO2 fluxes in the subtropical forest in the dry season (October-March) was 62.2% of the annual total from the whole forest ecosystem. On average, 43.3% of the net annual carbon sink occurred between October and December, indicating that this time period is an important stage for uptake of CO2 by the forest ecosystem from the atmosphere. Carbon uptake in the evergreen forest ecosystem is an indicator of the interaction of between the atmosphere and the canopy, especially in terms of driving climate factors such as temperature and rainfall events. We found that the Dinghushan evergreen forest is acting as a carbon sink almost year-round. The study can improve the evaluation of the net carbon uptake of tropical monsoon evergreen forest ecosystem in south China region under climate change conditions. 相似文献
17.
该文概述了北半球和我国气候变暖中增温的非对称性特征:北半球气候变暖存在明显的季节差异和昼夜不同步性, 大部分地区冬、春季升温高于夏、秋季, 日最低气温升幅是日最高气温升幅的2~3倍; 近50年我国近地表气温升高主要是最低气温明显上升的结果, 日最低气温升幅是日最气高温升幅的2~3倍, 与北半球基本一致; 升温最显著的季节为冬季和春季。在此基础上概述了非对称性增温对农业生态系统的影响, 论述了非对称性增温对农作物物候和农作物产量的影响, 得出最低气温升高促使整个生长季延长, 促使早春作物物候期提前, 但最低气温和最高气温对不同作物的物候以及同一作物的不同发育阶段影响不同。现有研究多采用模型或统计的方法研究气候变暖对作物生长的影响, 认为温度升高对作物有“强迫成熟”效应; 而现有的最低气温升高和最高气温升高对作物生长影响的研究结果并不一致。非对称性增温对农作物影响的实验研究极少, 且缺乏对模型模拟结果的实验验证。 相似文献