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1.
慕士塔格夏季近地表大气CO2浓度变化特征   总被引:4,自引:1,他引:3  
郑伟  姚檀栋  徐柏青 《冰川冻土》2005,27(2):213-219
利用CIRAS SC型号的CO2和H2O分析仪, 对东帕米尔高原慕士塔格地区2003年夏季(6~8月)近地表大气CO2浓度和水汽进行精确持续观测, 给出了我国内陆高原大气近地表 CO2 浓度夏季的变化特征. 观测表明, 该地夏季CO2浓度呈整体下降趋势, 并因受陆地植被光合作用、呼吸作用和土壤微生物等的影响, 有明显的日周期变化. 在短时间尺度上, 其变化趋势与瓦里关站点观测结果基本一致, 与Mauna Loa站点观测结果差别明显. 通过考察当地 CO2浓度与大气水汽的关系, 发现两者具有很显著的反相关性. 上述现象揭示, 慕士塔格近地表大气CO2含量的变化不仅受植物光合作用的影响,同时大气中水汽的含量在控制CO2含量方面起着重要作用.  相似文献   

2.
氧化亚氮(N2O)是一种重要的温室气体,对臭氧层具有破坏作用。在微藻培养过程中以及富营养化湖泊等以微藻为基础的生态系统中,已经观察到N2O的排放。然而,对于藻类中N2O收支平衡的重要作用以及潜在的藻类N2O产生途径却鲜有报道。综述了近年来藻类排放和吸收N2O的相关研究,主要内容包括藻类与N2O关系研究的发展历程、N2O在藻类体内产生和消耗的几种可能途径、藻类微环境对N2O分布格局的影响及其潜在的对全球气候变化的影响。鉴于政府间气候变化专门委员会目前没有考虑藻类水华或藻类养殖期间可能产生N2O排放,呼吁在全球范围内加强藻类N2O生产相关的实验研究,为全面理清藻类在N2O排放和吸收中的重要作用,全面评估水生生态系统温室气体排放提供支撑。  相似文献   

3.
疏勒河上游多年冻土区植物生长季主要温室气体排放观测   总被引:1,自引:1,他引:0  
选取青藏高原东北部疏勒河上游多年冻土区的高寒草甸样地为研究对象, 对2011年植物生长季(6-10月)主要温室气体(CO2、 CH4CH4和CO2)的排放进行了观测. 结果显示: 疏勒河上游多年冻土区高寒草甸地表CO2、 CH4和N2O排放速率范围分别为7.58~418.60 mg·m-2·h-1, -0.20~0.14 mg·m-2·h-1和-27.22~39.98 μg·m-2·h-1. 0~10 cm土壤温度、 含水量和盐分与CO2和CH4排放速率显著相关, 但与N2O排放速率无显著相关. 日均排放速率显示, CO2和N2O在整个观测期均表现为排放; CH4在植物返青期和生长旺盛期表现为排放, 在枯黄期伴随表层土壤发生日冻融循环时为吸收. 从9月30日12:00-10月6日14:40, 表层0~10 cm土壤经历了3次日冻融循环, CO2和N2O日均排放速率分别由冻融前的60.73 mg·m-2·h-1和9.91 μg·m-2·h-1提高到122.33 mg·m-2·h-1和11.70 μg·m-2·h-1. 土壤温度、 含水量和盐分是影响CO2和CH4排放的重要因子, 表层土壤冻融交替作用可提高地表CO2和N2O的排放速率.  相似文献   

4.
对取自赣南地区10个温泉的地热气体进行了气体化学成分及氦、碳、氖同位素组成的分析。该区地热气体可分为CO2型和N2型两种类型。CO2型地热气体分布在赣南东南部地区,主要成分是CO2,占总体积96.47%以上,二氧化碳气体的δ13C值为 -5.50‰~-3.49‰(PDB),平均为 -4.66‰,为幔源无机成因,其氦同位素组成为1.36~2.27 Ra,具有明显的幔源成因特征,最高约有28.2%的氦源于地幔,其N2-Ar-He关系研究表明,该型地热气体中的氮源于地幔-地壳-大气混合成因。研究揭示该区CO2型地热气体属幔源无机成因气,是地幔脱气作用的产物。N2型地热气体分布在赣南西部地区,N2含量占91.04%以上,其中二氧化碳气体的δ13C值为 -23.7‰~-12.6‰,平均为 -17.82‰,为壳源有机成因,其氦同位素组成为0.06~0.13 Ra,具有明显的壳源放射性成因特征,3He/4He 与 4He/20Ne关系和He-Ar-N2关系研究表明,N2型温泉气主要来源于大气,并有壳源气体的贡献。  相似文献   

5.
多年冻土区森林土壤是重要碳库,对于全球CO2、N2O和CH4平衡具有重要意义,冻融循环是多年冻土区的重要特征,但冻融作用对不同林型腐殖土有机质分解和温室气体排放的影响需进一步研究。本研究对兴安落叶松林(针叶林)、白桦林(阔叶林)、兴安落叶松和白桦混交林(针阔混交林)三种林型的腐殖层土壤进行了42天的短期室内培养实验,探索冻融作用对土壤理化性质和温室气体排放的影响。结果表明,冻融导致森林腐殖层土壤溶解性有机碳(DOC)增加,针叶林、阔叶林和针阔混交林分别增加了314.8%、91.4%和43.2%,但冻融后短期内土壤有机碳分解的温度敏感性(Q10)均明显下降,CO2排放量在25℃时分别下降24.7%、36.4%和29.5%。同时冻融作用也降低了森林土壤吸收CH4的能力,但没有发现对土壤N2O排放产生明显影响。冻融作用短期内降低了森林土壤温室气体全球增温潜势(GWP),其中对CO2的抑制作用最为明显,阔叶林腐殖层土壤受...  相似文献   

6.
控制灌溉对稻田CH4和N2O综合排放及温室效应的影响   总被引:6,自引:0,他引:6       下载免费PDF全文
采用静态箱-气象色谱法对控制灌溉稻田CH4和N2O排放进行了观测,研究控制灌溉模式对稻田CH4和N2O排放的影响,并对其温室效应进行了评估。结果表明,控制灌溉稻田CH4排放通量明显低于淹水灌溉稻田,且主要集中在分蘖前期和中期,全生育期CH4排放量比淹水灌溉稻田减少73.2%~85.0%。控制灌溉稻田N2O排放通量在水稻全生育期大部分时间都要大于淹水灌溉稻田,稻季N2O排放量分别为106.65 mg/m2和96.40 mg/m2,控灌稻田较淹灌稻田增加了10.6%。控制灌溉稻田稻季排放CH4和N2O的全球增温潜势(GWPs)为726 kg/hm2,较淹水灌溉稻田减少了59.1%。控制灌溉模式能显著降低CH4和N2O综合排放的全球增温潜势。  相似文献   

7.
西天山阿希金矿流体包裹体研究   总被引:4,自引:0,他引:4  
沙德铭 《地质与资源》1998,7(3):180-188
西天山阿希金矿含金石英脉内流体包裹体粒度细小,形态多样,以单一液相为主.化学成分上属K+(Na+)-SO2-4(Cl-)型,其中阳离子成分以K+为主,Na+次之;阴离子成分以SO2-4为主,Cl-次之;气相成分以H2O、CO2为主,富含O2、N2等气体,还原性气体(H2、CH4、CO等)含量亦较高.成矿作用发生于浅成(300~900m)、低温(120~180℃)和较封闭的还原环境.成矿流体盐度低,主要为大气降水并混以少量火山成因的岩浆水.  相似文献   

8.
羟胺(NH2OH)是海洋中极为活跃的痕量氮素之一,是氨氧化、硝酸盐异化还原成铵和厌氧氨氧化等诸多氮循环过程的关键中间产物,是构架海洋氮循环网络的重要组成。同时,NH2OH也是温室气体氧化亚氮(N2O)的重要前体物,与海洋N2O的产生与释放紧密关联。因此,系统理解NH2OH在海洋中的源汇格局、时空变异及其调控机理,对刻画海洋氮循环以及气候效应至关重要。然而,由于NH2OH在海洋中纳摩尔级别浓度及其复杂、活跃的迁移转化过程,使得海洋学界对于NH2OH的认识仍不清晰。系统综述了当前关于海洋NH2OH的研究进展,重点总结了NH2OH潜在的源汇过程、测定方法及其对海洋N2O产生的可能贡献,以及海洋中NH2OH的分布特征及其潜在影响因素。最后,梳理了关于NH2OH测定和影响其分布的可能机理等方面存在的问题和难点,提出未来海洋NH...  相似文献   

9.
本研究分别利用顶空平衡法与qPCR技术测定了2018年春季黄、渤海5个典型站位柱状沉积物中甲烷(CH4)和氧化亚氮(N2O)浓度及产甲烷菌与硫酸盐还原菌功能基因拷贝数,并分析了其与间隙水中相关环境因子的关系。沉积物上方水文条件的差异以及其中复杂的碳氮生物地球化学过程使得CH4和N2O浓度呈现出明显的空间和垂直变化。结果显示,沉积物中CH4浓度为0.23~0.92 μmol·kg-1,N2O浓度为18.90~104.96 nmol·kg-1。总体来说,渤海沉积物中CH4和N2O平均浓度高于黄海。垂向分布上,CH4浓度均随深度增加逐渐升高, $\text{SO}_{4}^{2-}$浓度随深度增加逐渐降低,并与CH4浓度呈镜像关系,产甲烷菌与硫酸盐还原菌的丰度也遵循着同样规律,这表明沉积物中产甲烷作用受$\text{SO}_{4}^{2-}$浓度的抑制。 mcrA基因拷贝数平均值为渤海低于黄海。除3500-7站外,沉积物中mcrA基因拷贝数随深度增加而升高。各站位mcrA 基因丰度与CH4浓度均无显著相关性,且mcrA丰度与$\text{SO}_{4}^{2-}$浓度之间也未检测到显著相关性。dsrB基因拷贝数远高于mcrA基因拷贝数,且两者相差至少两个数量级。 dsrB基因拷贝数随深度逐渐增加,直至10 cm左右,随后至沉积物底部逐渐减少。各站位dsrB基因拷贝数与CH4浓度剖面略有镜像关系,但均未检测到显著负相关性。以上结果均表明沉积物中存在着同时消耗沉积物中$\text{SO}_{4}^{2-}$与CH4的其他作用。N2O浓度随深度增加先降低,在深度30 cm以下逐渐升高。间隙水中$\text{NO}_{3}^{-}$和$\text{NO}_{2}^{-}$浓度均随深度减小,同时$\text{NH}_{4}^{+}$浓度与其呈相反趋势。沉积物中N2O与$\text{NO}_{2}^{-}$及$\text{NO}_{3}^{-}$浓度均呈正相关,且前者相关性较高,说明反硝化作用是沉积物中N2O产生的主要过程。这些结果为进一步了解近岸陆架海域沉积物中CH4和N2O的来源、分布及碳氮生物地球化学循环提供了参考资料。  相似文献   

10.
气团来源对瓦里关地区颗粒物数谱分布的影响   总被引:5,自引:1,他引:4  
通过对2005年8月到2007年5月在瓦里关全球本底站观测的气溶胶数谱分布资料和同期后向轨迹资料分析,发现气团来源对瓦里关地区颗粒物的数浓度及其谱分布有显著影响.气团起源于瓦里关东北部地区或者途径东北部地区,传输路径较短,传输速度相对较慢,大气中出现较高数浓度的爱根核模态颗粒物;气团来源于瓦里关西部或者两北地区时,传输路径较长,传输速度较快,大气中一般出现较高浓度的核模态颗粒物.  相似文献   

11.
Nitrous oxide is an important greenhouse gas,which has a long lifetime of about 120 years and has a 310 times greenhouse effect than CO2. Since the industrial revolution, the atmospheric N2O concentration has increased significantly by 20%. Ocean is a net source, about 1/3 of total oceanic souce. Southern Ocean is an important part of the global ocean system, has a unique hydrological characteristics. So far it is regarded as a significant natural source to the global N2O flux according to the model studies. However,the field work is very limit, due to the fierce in situ conditions. The importance of N2O reseaches of Southern Ocean, progresses of nitrous oxide researches, especially new technologies applied to underway N2O measurements in the Southern Ocean are reviewed. The advance of field, model studies and their problems or uncertainties that need to be resolved are also discussed. The using of stable isotope methods will provide powerful tools for marine N2O mechanism. Development of high precision monitoring technology is generally the driving force of future research. Developing techniques of laser spectroscopy in marine N2O studies and measurment of N2O in sea ice will provide powerful tools to differeciate the N2O source sink characteristic, constrain their budget and formation mechanism in region such as Southern Ocean.  相似文献   

12.
北京地区大气主要温室气体的季节变化   总被引:7,自引:0,他引:7  
摘 要:报道了北京主要温室气体浓度最新变化情况,采用1993—2002年北京主要温室气体周平均浓度的数据,用时间序列分解的方法对其季节变化进行了分析研究,并对造成北京主要温室气体季节变化的原因进行了初步探讨。分析发现北京大气CH4的季节变化范围在-49.2×10- 9~ 55.7×10- 9(V/V)之间,并呈现出双峰模态;北京大气CO2浓度的季节变化范围在-26.4×10- 6~ 34.0×10- 6(V/V)之间;北京大气 N 2 O浓度变化没有明显的季节变化特点。  相似文献   

13.
长江中下游六省大气甲烷柱浓度时空分布   总被引:2,自引:0,他引:2  
甲烷(CH4)是造成气候变暖的主要温室气体之一。为了了解长江中下游水稻种植区CH4浓度的分布情况,本次研究基于温室气体观测卫星(greenhouse gases observing satellite,GOSAT)和大气红外探测仪(atmospheric infrared sounder,AIRS)卫星反演的数据产品,对我国长江中下游六省大气CH4柱浓度的时空分布特征进行了研究。研究结果表明,由GOSAT反演的长江中下游六省大气CH4浓度呈逐年增长趋势,其年均浓度由2011年的1817×10?9增长至2018年的1875×10?9,高于东三省、华北平原和全国平均水平。区域平均年增长量为8.2×10?9 a?1。各省年际增长幅度略有差异,纬度偏低的江西、湖南和浙江三省大气CH4浓度高且增长量偏大,纬度偏高的湖北、安徽和江苏三省大气CH4浓度略低且增长量偏小。长江中下游六省大气CH4呈现较强的季节变化特征,湖北、湖南、江西和浙江峰值出现在9月,安徽、江苏峰值出现在8月。垂直方向上长江中下游六省CH4浓度随气压降低,浓度逐渐减小,呈现出明显的季节变化特征,近地面层GOSAT反演的最高值出现在夏季,最低值出现在春季;高层最高值出现在秋季,最低值出现在春季。AIRS反演的大气CH4浓度空间分布上北高南低,与GOSAT反演结果不一致,可能由于AIRS主要反映了对流层中层大气状况而GOSAT更多的反映了近地面层大气CH4的变化。其垂直方向上呈现高度越高,浓度越低,不同高度上秋季浓度均最高。  相似文献   

14.
羊卓雍错流域降水中稳定氧同位素变化特征   总被引:4,自引:0,他引:4  
根据青藏高原南部羊卓雍错流域白地、翁果和堆乡3个水文站2004年1~10月降水中δ18O的测定结果,分析了该流域降水中δ18O的变化特征及其与温度和降水量之间的关系.结果表明:3个站点降水中δ18O的值在雨季前变化不大,且都保持相对高值;进入雨季后都开始下降,雨季结束后又均开始增大.该流域夏季降水中δ18O表现出低值的特征与夏季西南季风的强烈活动密切相关.受西南季风影响,3个站点夏季降水均表现出季风降水的特征,降水中δ18O与降水时温度关系不明显,而与降水量之间存在着一定的反向变化趋势,从而表现出一定的“降水量效应”.羊卓雍错流域降水中δ18O的这种变化特征与拉萨的基本一致.  相似文献   

15.
Temporal distribution of southwest monsoon (June –September) rainfall is very useful for the country’s agriculture and food grain production. It contributes more than 75% of India’s annual rainfall. In view of this, an attempt has been made here to understand the performance of the monthly rainfall for June, July, August and September when the seasonal rainfall is reported as excess, deficient or normal. To know the dependence of seasonal rainfall on monthly rainfall, the probabilities of occurrence of excess, deficient and normal monsoon when June, July, August and also June + July and August + September rainfall is reported to be excess or deficient, are worked out using the long homogenous series of 124 years (1871-–1994) data of monthly and seasonal rainfall of 29 meteorological sub-divisions of the plain regions of India. In excess monsoon years, the average percentage contribution of each monsoon month to the long term mean (1871–1994) seasonal rainfall (June –September) is more than that of the normal while in the deficient years it is less than normal. This is noticed in all 29 meteorological sub-divisions. From the probability analysis, it is seen that there is a rare possibility of occurrence of seasonal rainfall to be excess/deficient when the monthly rainfall of any month is deficient/excess.  相似文献   

16.
The purpose of this study is to investigate the atmospheric water cycle in Lanzhou and surrounding areas, a place sensitive to climatic conditions and located in the vertex of the “Monsoon Triangle” of China; this study obtained 243 event-based precipitation samples from four stations in Lanzhou, Yongdeng, Yuzhong and Gaolan for 1 year from April 2011 to March 2012. The seasonal variations of δ 18O and d excess indicate that westerly water vapor, local moisture and summer monsoon all have an influence in this region on a large scale. The westerlies play a dominant role. However, the impact of monsoon moisture has a seasonal limitation, mainly during the period from June to early August. On a local scale, the transportation of moisture appears via two routes. The contribution rate of recycling moisture, over the region, is only 3.6 % on average due to the deficiency of water resource in arid and semi-arid land. Additionally, the effect of secondary evaporation has also been discussed, and the results show that relative humidity, temperature and precipitation amount have different impacts on the effect. However, the influence of precipitation amount is not obvious when the rainfall amount is below 10 mm, while the meteorological parameters of relative humidity and temperature play a significant role in that scope.  相似文献   

17.
Atmospheric Deposition (AD) provides external nutrients such as nitrogen (N), phosphorus (P) and iron (Fe) supporting the growth of phytoplankton in oceans and thereby exerts obvious impacts on carbon and nitrogen cycles and climate change associated. Specifically, the external nutrients derived from atmospheric deposition can promote the marine primary production and nitrogen fixation that enhance the ocean capacity in absorbing CO2; AD may also change a few pathways of carbon and nitrogen cycles in oceans and increase the emissions of biogenic aerosol and radioactive gases such as N2O, DMS, etc. Due to the underlying important impacts on climate and environmental change, AD and processes related have become the hot topics of multidisciplinary studies in the areas of ocean and atmospheric sciences, and the focus of some international core projects such as Surface Ocean Lower Atmosphere Study (SOLAS), an International Study of Marine Biogeochemical Cycles of Trace Elements and Their Isotopes (GEOTRACES) and Integrated Marine Biogeochemistry and Ecosystem Research (IMBER). With the severe air pollution and high frequencies of Asian dust events, as the downwind areas of big cities and dust sources, the East China Sea and adjacent North Pacific have received increasing influences of AD. Limited studies showed that the increase of AD indeed caused significant influence on carbon and nitrogen cycles in these immediately related oceanic areas and the study there would have a signature effect on global oceans. A multidisciplinary study on the impacts of AD in oceans, e.g., combing molecular biology and experimental ecology techniques to study primary production processes, utilizing isotopic techniques to trace the change of the nitrogen cycle, new evidences of ocean-biogenic aerosol emissions, etc. would be the focus in the future.  相似文献   

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