土壤环境因子对克氏针茅草地生态系统碳通量的影响     

薛红喜  李琪  黄瑜  王云龙  吴东丽 《地理科学》2014,(11):1393-1398

利用涡度相关法对克氏针茅草地生态系统的生态系统初级生产力(GEP)、生态系统呼吸(RECO)和净生态系统碳交换(NEE)进行观测,探讨土壤环境因子对GEP、RECO、NEE的影响。结果表明:2009~2010年,克氏针茅草地生态系统GEP、RECO、NEE都呈现出了明显的峰值变化规律,2010年表现出了更强的固碳能力。土壤环境因子与克氏针茅草地生态系统GEP、RECO、NEE都有极显著的相关性,土壤温度对碳通量组分的影响程度要高于土壤水分;土壤环境因子对GEP、RECO的影响程度要高于对NEE的影响。  相似文献   

西藏高原高寒嵩草草甸在不同降雨条件下CO_2通量的生物物理调节机制（英文）     

《资源与生态学报(英文版)》2017,(1)

降雨的年际变化可导致碳通量显著变化。因此我们利用涡度相关(EC)技术观测西藏高原北部的一个高寒草甸连续2年(2005–2006)的CO2净生态系统交换(NEE),以分析不同降水年份下CO_2通量的差异和控制因素。2005和2006年的降水量分别为489.9 mm和241.1 mm,相比于476.0 mm的多年平均值,前者属于平水年,后者属于干旱年。2006年的NEE的年际累积表现为净排放量(87.70 g C m~(-2) yr~(-1)),而2005年则表现为非常微弱的吸收(-2.35 g C m~(-2) yr~(-1))。因此该高寒草甸在平水年是碳中性的,但在干旱年是碳源,这说明如果未来气候变暖继续恶化加剧土壤干旱的条件下,高寒草甸有可能成为一个CO_2释放源。在干旱年份,总初级生产力(GEE)、叶面积指数(LAI)以及生态系统碳吸收持续的时间都明显降低,由此引发干旱年份生长季旺盛时期每日NEE最大吸收速率、最大光合速率(Pmax)以及表观量子效率(α)只是平水年的30%–50%。在其他因子的调控方面,半小时尺度的GEE和NEE与光合有效辐射(PAR)密切相关,但这种响应会受空气温度(T_a),土壤水分含量(SWC)和水汽压亏缺(VPD)的影响。NEE的吸收速率会随着T_a和VPD的升高以及SWC的下降而减少。当PAR超过合适的范围值时,由于较高的辐射加剧了土壤干旱的情况,会减少白天NEE的吸收速率。NEE吸收速率的最适T_a和VPD值分别为12.7℃和0.42 KPa,而且NEE的吸收速率也会随着SWC的增加而增大。LAI的季节变异能够解释GEE和NEE变异的77%。半小时尺度上的生态系统呼吸(R_e)的变异主要依赖于土壤温度(T_s),但SWC会在一定程度上调控R_e对T_s的响应。  相似文献   

巴丹吉林最高沙山区CO₂浓度与昼夜变化规律   总被引：1，自引：0，他引：1  

赵景波  邵天杰  吕晓虎  侯雨乐  董治宝 《地理研究》2010,29(11):1993-2003

为查明沙漠区CO₂浓度和对大气CO₂的影响以及在全球碳循环中的作用,利用红外CO₂监测仪,在2009年5月对全球最高大的巴丹吉林诺尔图东大沙山等进行了17个钻孔CO₂浓度的昼夜观测。结果表明,巴丹吉林大沙山不同观测点CO₂浓度差异较大,各观测点CO₂浓度变化在0.01%~0.075％之间;夜间沙层CO₂浓度低,白天CO₂浓度高;CO₂浓度昼夜变化明显,从早7时到次日7时1~5m各深度CO₂浓度均呈现由低到高再到低的变化规律;在24h内,沙层CO₂浓度变化存在4个转折点,分别出现在凌晨5时、11时、18时和21时左右。在沙层水分一定的条件下,昼夜温度变化是造成沙层CO₂浓度昼夜规律变化的主要原因,两者呈正相关关系;含水量较高的沙层CO₂浓度明显高于含水量较低的沙层;5m深度以上沙层CO₂浓度均高于地表空气CO₂浓度,表明极端干旱的高大沙山区是CO₂的来源区,也指示环境恶劣的裸露高大沙山区微生物活动产生的沙层CO₂浓度仍然超过了大气CO₂浓度。  相似文献   

过去陆地生态系统碳储量估算研究   总被引：1，自引：0，他引：1  

遇蕾  任国玉 《地理科学进展》2007,26(3):68-79

准确估算陆地生态系统碳储量并认识其空间分布和时间演变规律是碳循环研究的关键 问题。本文回顾了全球与中国陆地生态系统在碳储量估算研究方面的若干进展, 包括基于各种方 法和资料的主要估算结果及其尚存在的不确定性。重点评述了末次盛冰期和中全新世两个时期 陆地生态系统碳储量的变化及其影响因素, 对8.2kaB.P.以来全球大气CO₂ 浓度呈现升高的现象 及其可能原因进行了讨论。全新世中晚期全球大气CO₂ 浓度逐渐升高与旧大陆地区陆地生态系 统碳储量减少的事实是一致的, 新石器时期特别是农业文明开始以后人类活动对陆地植被的持 续干预可能是造成陆地生态系统碳储量减少的原因之一。  相似文献   

干旱对青藏高原腹地高寒草地生态系统净CO2交换的影响     

赵玉萍  张宪洲  石培礼  王景升  武建双 《资源与生态学报(英文版)》2013,(4):327-336

干旱对草地生态系统NEE有深刻影响。基于涡度相关技术提供的碳通量及小气候数据,研究了2009年当雄高寒草地生态系统的碳交换特征及其主控因子,同时分析了干旱的可能影响。5—7月初及9月发生的干旱导致草地GLAI、ALB和GPP较低,6月中旬到7月初碳吸收一度下降。干旱使6、7月份NEE日变化进程发生改变。同时,NEE和GPP的季节变化也受到干旱影响。由于干旱导致生态系统吸收能力降低,75]3日出现NEE日净碳排放最高值（0．9gCm-2d-1）。5-7月的NEE月总量均大于0,且逐月增加。该草地2009年的GPP和NEE分别为-158．1和52．4gCm。日均0〈01时,0成为影响白天NEE变化的主控因子。GLAI、r和目是3个对NEE季节变异影响最大的指标,且其影响程度依次降低。GPP季节变化的主控因子是GLAI、θ、PPT、VPD和瓦,生态系统水分状况（0、PPT或VPD）对GPP的影响大于T20。Rcco主要受控于t、GLAI、PAR和PPT,且其影响力依次降低。GLAI的季节变化可解释NEE和GPP变异的60．7％和76．1％。当雄高寒草地生态系统水分条件的年际变化可能是影响NEE年际变异的主要因子。  相似文献   

亚热带马尼拉草坪生态系统CO2净交换量测定方法比较   总被引：3，自引：0，他引：3  

李熙波  杨玉盛  曾宏达  谢锦升  张静  朱宁 《亚热带资源与环境学报》2008,3(4)

利用IRGA法和GC法,同步观测了3种天气(晴天、多云、阴天)条件下福州市江滨公园马尼拉草坪生态系统CO2净交换量(NEE)的白昼动态变化,比较IRGA法和GC法透明通量箱对观测样点环境的影响程度,并探讨其对NEE观测结果的影响.结果表明:在单次观测结束时,IRGA法通量箱对样点环境的扰动小于GC法,晴天白天二者箱内的平均升温分别为179 ℃和233 ℃,箱内平均光合有效辐射(PAR)降低幅度分别为1100%和2100%.3种天气情况下,IRGA法与GC法观测的NEE白天变化趋势较一致,但3种天气相同时段内GC法测定的NEE平均值比IRGA法高317 μmol·m-2·s–1,二者的差异在中午最大,在清晨和傍晚较小.IRGA法比GC法可以更为准确地测量草坪NEE.  相似文献   

亚热带马尼拉草坪生态系统CO_2净交换量测定方法比较     

李熙波  杨玉盛  曾宏达  谢锦升  张静  朱宁 《福建地理》2008,(4)

利用IRGA法和GC法,同步观测了3种天气(晴天、多云、阴天)条件下福州市江滨公园马尼拉草坪生态系统CO2净交换量(NEE)的白昼动态变化,比较IRGA法和GC法透明通量箱对观测样点环境的影响程度,并探讨其对NEE观测结果的影响.结果表明:在单次观测结束时,IRGA法通量箱对样点环境的扰动小于GC法,晴天白天二者箱内的平均升温分别为1.79℃和2.33℃,箱内平均光合有效辐射(PAR)降低幅度分别为11.00%和21.00%.3种天气情况下,IRGA法与GC法观测的NEE白天变化趋势较一致,但3种天气相同时段内GC法测定的NEE平均值比IRGA法高3.17μmol·m-2·s-1,二者的差异在中午最大,在清晨和傍晚较小.IRGA法比GC法可以更为准确地测量草坪NEE.  相似文献   

青藏高原高寒草甸生态系统CO₂通量研究进展     

乔春连  李婧梅  王基恒  葛世栋  赵亮  徐世晓 《山地学报》2012,(2):248-255

高寒草甸是广布于青藏高原的主要植被类型,它是青藏高原大气与地面之间生物地球化学循环的重要构成部分,在区域碳平衡中起着极为重要的作用。基于对青藏高原主要高寒草甸生态系统类型CO2通量研究方面的综述,系统分析了高寒草甸生态系统CO2通量日、季、年等不同时间尺度的变化特征以及温度、光合有效辐射、降水等主要环境因子对高寒草甸生态系统CO2通量的影响;同时,结合其他地区草地生态系统,就青藏高原三种典型高寒草甸生态系统类型源汇效应和Q10值进行了比较;最后,结合青藏高原高寒草甸生态系统CO2通量研究的现实与需要,提出了当前存在一些不确定性和有待深入研究的问题。  相似文献   

围封和放牧对科尔沁沙质草地净生态系统碳交换量的影响北大核心CSCD     

孙殿超  李玉霖  赵学勇  罗亚勇  毕京东 《中国沙漠》2016,(1):93-102

利用箱式法对科尔沁地区围封和放牧条件下的沙质草地净生态系统碳交换量(NEE)进行研究,以探讨围封、放牧对NEE的影响。结果显示:(1)围封17年样地的NEE显著小于围封22年样地的,围封22年样地的显著小于放牧样地的(P<0.01)。(2)在植物生长季内,围封样地总体表现出碳汇功能,放牧样地表现出碳源功能。(3)从碳净固定的量来看,围封17年沙质草地的净碳固定能力强于围封22年的;而围封22年比围封17年的沙质草地的在净碳固定方面持续的时间较长。(4)不同环境因子对不同处理NEE的影响程度不尽相同,其线性组合最大可解释NEE的变异依次为围封22年(39.5%)>围封17年(32.1%)>放牧(21.2%)。  相似文献   

青藏高原高寒草原区域碳估测   总被引：16，自引：1，他引：15  

裴志永  周才平  欧阳华  杨文斌 《地理研究》2010,29(1):102-110

CASA(Carnegie-Ames-Stanford Biosphere)模型是一个表征陆地生态系统水、碳素和氮素通量随时间变化的生态系统过程模型。本研究采用MODIS遥感数据与CASA模型相结合的方法计算了青藏高原高寒草原生态系统植被净初级生产力(NPP)总量为20.57×10¹²g·a^-1的碳。同时根据五道梁实验点上得到的经验关系估算了青藏高原高寒草原生态系统区域上的土壤碳排放(Heterotrophic respiration)总量为8.07×10¹² g·a^-1,因此推算得高寒草原区域内净生态系统生产力(NEP)折算成碳为12.50×10¹² g·a^-1。  相似文献   

Cloudy Sky Conditions Promote Net Ecosystem CO2 Exchange in a Subtropical Coniferous Plantation across Seasons     

HAN Jiayin  YE Shu  GUO Chuying  ZHANG Leiming  LI Shenggong  WANG Huimin 《资源与生态学报(英文版)》2019,10(2):137-146

Dynamic changes in solar radiation have an important influence on ecosystem carbon sequestration, but the effects of changes caused by sky conditions on net ecosystem CO₂ exchange (NEE) are unclear. This study analyzed the effects of sunny, cloudy, and overcast sky conditions on NEE using carbon flux and meteorological data for a subtropical coniferous plantation in 2012. Based on one-year data, we found no seasonal variation in the light response curve under various sky conditions. Compared with sunny sky conditions, the apparent quantum yield (α) and potential photosynthetic rate at a light intensity of 150 and 750 W m^-2 (P₁₅₀ and P₇₅₀) under cloudy sky conditions increased by an average of 82.3%, 217.7%, and 22.5%; α and P₁₅₀ under overcast sky conditions increased by 118.5% and 301% on average. Moderate radiation conditions were more favorable for maximum NEE, while low radiation conditions inhibited NEE. In most cases, when the sunny NEE was used as a baseline for comparison, the relative change in NEE (%NEE) was positive under cloudy sky conditions and negative under overcast sky conditions. The average maximal %NEE under cloudy sky conditions was 42.4% in spring, 34.1% in summer, 1.6% in autumn and -87.3% in winter. This study indicates that cloudy sky conditions promote photosynthetic rates and NEE in subtropical coniferous plantations.  相似文献   

Comparing the seasonal variation of parameter estimation of ecosystem carbon exchange between alpine meadow and cropland in Heihe River Basin, northwestern China     

HaiBo Wang  MingGuo Ma 《寒旱区科学》2015,7(3):216-228

Grasslands and agro-ecosystems occupy one-third of the global terrestrial area. However, great uncertainty still exists about their contributions to the global carbon cycle. This study used various com...  相似文献   

Biophysical Regulation of Carbon Flux in Different Rainfall Regime in a Northern Tibetan Alpine Meadow     

CHAI Xi  SHI Peili  ZONG Ning  NIU Ben  HE Yongtao  ZHANG Xianzhou 《资源与生态学报(英文版)》2017,8(1):30-41

Inter-annual variability in total precipitation can lead to significant changes in carbon flux. In this study, we used the eddy covariance (EC) technique to measure the net CO₂ ecosystem exchange (NEE) of an alpine meadow in the northern Tibetan Plateau. In 2005 the meadow had precipitation of 489.9 mm and in 2006 precipitation of 241.1 mm, which, respectively, represent normal and dry years as compared to the mean annual precipitation of 476 mm. The EC measured NEE was 87.70 g C m^-2 yr^-1 in 2006 and -2.35 g C m^-2 yr^-1 in 2005. Therefore, the grassland was carbon neutral to the atmosphere in the normal year, while it was a carbon source in the dry year, indicating this ecosystem will become a CO₂ source if climate warming results in more drought conditions. The drought conditions in the dry year limited gross ecosystem CO₂ exchange (GEE), leaf area index (LAI) and the duration of ecosystem carbon uptake. During the peak of growing season the maximum daily rate of NEE and P_max and α were approximately 30%-50% of those of the normal year. GEE and NEE were strongly related to photosynthetically active radiation (PAR) on half-hourly scale, but this relationship was confounded by air temperature (T_a), soil water content (SWC) and vapor pressure deficit (VPD). The absolute values of NEE declined with higher T_a, higher VPD and lower SWC conditions. Beyond the appropriate range of PAR, high solar radiation exacerbated soil water conditions and thus reduced daytime NEE. Optimal T_a and VPD for maximum daytime NEE were 12.7℃ and 0.42 KPa respectively, and the absolute values of NEE increased with SWC. Variation in LAI explained around 77% of the change in GEE and NEE. Variations in R_e were mainly controlled by soil temperature (T_s), whereas soil water content regulated the responses of Re to T_s.  相似文献   

青藏高原太阳辐射对高山草甸净生态系统二氧化碳的影响(英文)     

范玉枝  张宪洲  王景升  石培礼 《地理学报(英文版)》2011,21(4):666-676

On the Tibetan Plateau, the alpine meadow is the most widespread vegetation type. The alpine meadow has a low biological productivity and low vegetation coverage in the growing season. The daytime NEE between the atmosphere and the alpine meadow ecosystem was influenced by solar radiation. To analyze the characteristics of change in NEE and to calculate the parameters related to photosynthesis and respiration in different solar radiation environments, the NEE measurements were taken in Damxung from July to August in 2003, 2004, 2005 and 2006 using the eddy covariance technique. Solar radiation was grouped into three levels according to the net radiation, which was more than 155 W m-2 d-1 on clear days, 144±5 W m-2 d-1 on partly cloudy days and less than 134 W m-2 d-1 on cloudy days. The diurnal relationships between NEE and PAR varied with differences in solar radiation, which was a rectangular hyperbola form on clear days, two different concave curves on partly cloudy days and an irregular triangle form on cloudy days. The mean CO2 absorption rate showed a decreasing trend with increasing solar radiation. The daytime absorption maximum occurred around 10:00 on clear days with an average of slightly less –0.2 mg m-2 d-1, around 11:00 on partly cloudy days with an average of about –0.2 mg m-2 d-1, and around 12:00 on cloudy days with an average of about –0.25 mg m-2 d-1. As solar radiation increased, the Amax and the Q10 decreased. However, the R10 increased and the maximum of the α occurred on partly cloudy days. The optimum net solar radiation was about 134–155 W m-2 d-1, which induced a PAR of about 1800-2000 μmol m-2 s-1 and soil temperature at a depth of 5 cm of about 14℃. Therefore, on the Tibetan Plateau, the alpine meadow ecosystem will have a higher carbon absorption potential while solar radiation decreases in the future.  相似文献   

高寒草甸土壤有机碳储量及其垂直分布特征   总被引：24，自引：0，他引：24  

陶贞  沈承德  高全洲  孙彦敏  易惟熙  李英年 《地理学报》2006,61(7):720-728

青藏高原是全球变化的敏感区。高寒草甸草原是青藏高原上最主要的放牧利用草地资源之一。选择青藏高原东北隅海北站内具有代表性的高寒草甸土壤进行高分辨率采样,测定土壤根系和有机碳含量。研究得出,青藏高原高寒草甸土壤贮存有巨大的根系生物量 (23544.60 kg ha^-1~27947 kg ha^-1) 和土壤有机碳 (21.52 GtC);自然土壤表层 (0~10 cm) 储存了整个剖面土壤有机碳总量的30%左右。比较发现,高寒草甸土壤的有机碳平均贮存量 (23.17×10⁴ kgCha^-1) (0~60 cm) 较相应深度的热带森林土壤、灌丛土壤和草地土壤的有机碳贮存量高约1~5倍多。在全球碳预算研究中,青藏高原高寒草甸土壤有机碳库不可忽视。随着全球变暖,表层土壤有机碳分解释放的CO₂将增加。为了减少高寒草甸生态系统的碳排放,应加强高寒草甸土壤地表覆被的保护,合理种植深根系植物。这对减缓全球大气CO₂浓度升高的速率以及可持续开发高寒草甸的生态服务功能都具有重要意义。  相似文献   

重庆金佛山岩溶区表层岩溶生态系统CO2浓度分析   总被引：4，自引：0，他引：4  

李林立  高波  蒋勇军  况明生  谢世友  刘玉  张远瞩 《热带地理》2004,24(4):326-331

以重庆金佛山林地、裸地表层岩溶生态系统CO2浓度的实际观测资料为基础,探索表层岩溶系统CO2浓度变化规律.结果显示,这种变化与土壤温度有密切关系,林地与裸地各个层次土壤的CO2浓度与土温呈一致性变化,这构成了表层岩溶生态系统对外界条件的灵敏响应.研究进一步揭示了林地植被平抑这种动态效应,而裸地则响应于温度变化.  相似文献   

Ecosystem Carbon Allocation of a Temperate Mixed Forest and a Subtropical Evergreen Forest in China     

LUO Yiwei  ZHANG Leiming  GUO Xuebing  DAI Guanhua  WANG Anzhi  ZHOU Guoyi  YU Guirui 《资源与生态学报(英文版)》2018,9(6):642-653

Ecosystem carbon allocation can indicate ecosystem carbon cycling visually through its quantification within different carbon pools and carbon exchange. Using the ecological inventory and eddy covariance measurement applied to both a mature temperate mixed forest in Changbai Mountain (CBM) and a mature subtropical evergreen forest in Dinghu Mountain (DHM), we partitioned the ecosystem carbon pool and carbon exchange into different components, determined the allocation and analyzed relationships within those components. Generally, the total carbon stock of CBM was slightly higher than that of DHM due to a higher carbon stock in the arbor layer at CBM. It was interesting that the proportions of carbon stock in vegetation, soil and litter were similar for the two mature forests. The ratio of vegetation carbon pool to soil carbon stock was 1.5 at CBM and 1.3 at DHM. However, more carbon was allocated to the trunk and root from the vegetation carbon pool at CBM, while more carbon was allocated to foliage and branches at DHM. Moreover, 77% of soil carbon storage was limited to the surface soil layer (0-20 cm), while there was still plentiful carbon stored in the deeper soil layers at DHM. The root/shoot ratios were 0.30 and 0.25 for CBM and DHM, respectively. The rates of net ecosystem productivity (NPP) to gross ecosystem productivity (GPP) were 0.76 and 0.58, and the ratios of ecosystem respiration (Re) to GPP were 0.98 and 0.87 for CBM and DHM, respectively. The net ecosystem carbon exchange/productivity (NEP) was 0.24 t C ha^-1 yr^-1 for CBM and 3.38 t C ha^-1 yr^-1 for DHM. Due to the common seasonal and inter-annual variations of ecosystem carbon exchange resulting from the influence of environmental factors, it was necessary to use the long record dataset to evaluate the ecosystem sink capacity.  相似文献   

青藏高原草地生态系统碳收支研究进展   总被引：7，自引：3，他引：4  

王军邦  黄玫  林小惠 《地理科学进展》2012,31(1):123-128

陆地生态系统碳收支仍然是当前全球气候变化研究的重要内容,青藏高原作为全球气候变化的敏感区,使青藏高原草地生态系统在区域碳收支平衡中占有主导地位,但研究方法等不同使得碳收支估算结果存在很大的不确定性。气候变暖在一定程度上提高了高寒草地生态系统的植被初级生产力和生物量,由此补偿了气候变暖导致的土壤有机碳分解释量,使青藏高原草地植被仍然发挥着碳汇的功能。而人类放牧活动对草地生态系统的影响较为复杂。因此,如何区分气候变化和人类活动对生态系统的影响机制,定量评价未来气候变化和人类活动影响下,青藏高原生态系统碳源/汇格局的可能变化,是一个非常重要的研究方向,也是一个极大的挑战。  相似文献