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1.
中国的温室气体排放、减排措施与对策*   总被引:38,自引:0,他引:38       下载免费PDF全文
黄耀 《第四纪研究》2006,26(5):722-732
根据《中华人民共和国气候变化初始国家信息通报》,1994年中国温室气体排放总量约为3650×106t的CO2当量,其中CO2,CH4和N2O分别占73.1 % ,19.7 % 和7.2 % 。CO2排放主要来自能源活动,CH4排放主要来自农业活动和能源活动,N2O排放主要来自农业活动。在过去的20余年里,中国为减缓全球温室气体排放的增长速度做出了重要的贡献。对文献资料和大量研究结果的分析表明,中国可通过采取相关措施和制订相应政策进一步减少温室气体的排放。减少CO2排放的主要措施和对策包括:调整能源结构(降低煤炭消费比例、适度提高天然气比例和发展核能);提高能源生产、转化、分配和使用过程中的效率;开发利用水能、风能、太阳能和生物能等可再生能源;通过植树造林,推广秸秆还田、平衡施肥和少(免)耕等增加陆地生态系统的碳吸收。减少CH4排放的主要措施和对策包括:回收利用煤层气;改造生活垃圾填埋场地和筛选环境适应性强的CH4氧化菌并接种于填埋场;改善反刍动物的营养成分;稻田合理灌溉、提高水稻的收获指数、选育和种植CH4排放低的水稻品种等。减少农田N2O排放的主要措施和对策包括:提高氮肥利用率;推广施用长效肥和控释肥;施用生物抑制剂和实施微生物工程等。  相似文献   

2.
耕作措施对陕西耕作土壤碳储量的影响模拟*   总被引:6,自引:0,他引:6  
张凡  李长生  王政 《第四纪研究》2006,26(6):1021-1028
鉴于农业生态系统土壤有机碳(SOC)平衡对中国农业可持续发展的重要性,文章以陕西农业生态系统为对象,整合农业生物地球化学模型(DNDC)与陕西农业地理信息系统数据库,利用陕西地区气象和作物资料,对陕西省2000年作物生长发育和土壤碳循环进行了模型模拟,实例探讨了耕作管理对土壤碳储量的影响,并由此评价生物地球化学模型在气候变化、土壤性质及农业耕作管理措施对土壤碳含量影响方面的预测能力。敏感性分析表明土壤性状,尤其是初始有机碳含量是影响模型区域尺度模拟的最主要敏感因素。区域模拟使用灵敏系数分析法,分别采用敏感因子的最大、最小值驱动模型在每一模拟单元内的运算,以产生一个土壤有机碳变化的范围值,土壤有机碳变化的真实值应以较大机率包含在这一范围内。分析模拟结果可以得出3点结论: 1)2000年陕西耕作土壤总有机碳储量约为103TgC,是一个大气CO2源,向大气释放碳0.5TgC; 2)提高作物秸秆还田率是提高陕西农田碳库储量的有效可行措施,将作物秸秆还田率从当前的15 % 提高到50 % 或90 % 会使陕西农田土壤从大气CO2源转变为汇,每年分别增加土壤有机碳库储量0.7TgC或2.1TgC; 3)施用有机农肥(500kg/hm2)也会增加土壤碳输入,从而提高土壤碳储量,使陕西农田系统转变为较弱的碳(C)源,每年可多固定0.2TgC。  相似文献   

3.
全球变化条件下的土壤呼吸效应   总被引:52,自引:7,他引:52  
土壤呼吸是陆地植物固定CO2尔后又释放CO2返回大气的主要途径,是与全球变化有关的一个重要过程。综述了全球变化下CO2浓度上升、全球增温、耕作方式的改变及氮沉降增加的土壤呼吸效应。大气CO2浓度的上升将增加土壤中CO2的释放通量,同时将促进土壤的碳吸存;在全球增温的情形下,土壤可能向大气中释放更多的CO2,传统的土地利用方式可能是引发温室气体CO2产生的重要原因,所有这些全球变化对土壤呼吸的作用具有不确定性。认为土壤碳库的碳储量增加并不能减缓21世纪大气CO2浓度的上升。据此讨论了该问题的对策并提出了今后土壤呼吸的一些研究方向。其中强调,尽管森林土壤碳固定能力有限,但植树造林、森林保护是一项缓解大气CO2上升的可行性对策;基于现有田间尺度CO2通量测定在不确定性方面的进展,今后应继续朝大尺度田间和模拟程序方面努力;着重回答全球变化条件下的土壤呼吸过程机理;区分土壤呼吸的不同来源以及弄清土壤呼吸黑箱系统中土壤微生物及土壤动物的功能。当然,土壤呼吸的测定方法尚有待改善。  相似文献   

4.
北京斋堂黄土中主要温室气体组分特征   总被引:4,自引:3,他引:1  
刘强  刘嘉麒 《第四纪研究》1999,19(5):478-478
根据极地冰芯等资料已经重建了过去大气温室气体(主要是CO2,CH4)浓度的变化。由于人类活动的影响,温室气体的含量自工业革命以来有了明显的上升,其影响表现为全球变暖。如果维持现在的CO2产放水平,根据气候模式预测到下个世纪末全球温度将增加l-3.5℃,可能极大地改变人类生存的环境。但是预测结果还存在着很大的不确定性,其中一个重要因素是对温室气体的源和汇的理解还不完善,有相当数量的CO2声向不明(即未知汇).目前倾向认为,在北半球的中纬度地带可能存在着一个巨大的陆地生态系统汇(植被和土壤).中国黄土分布在北半球中纬度,实际上是在干旱一半干旱气候条件下形成的一套巨厚的成土作用较弱的黄土一古土壤序列。  相似文献   

5.
中国东部CO2气田(藏)发育广泛,分布复杂。本文对中国东部松辽、渤海湾、苏北、三水、东海、珠江口、莺琼、北部湾等盆地和内蒙古商都地区以及部分现代构造岩浆活动区CO2气田(藏)和气苗中CO2的地球化学特征进行了分析和研究,探讨了中国东部CO2气的成因、来源及分布。中国东部CO2气的含量主要分布区间为0~10%,其次为90%~100%,呈现典型的U字型。δ13CCO2值则呈现典型的单峰式分布,峰值区间为-6‰~-4‰。CO2含量、δ13CCO2值和R/Ra值综合表明,中国东部高含CO2气以幔源无机成因为主,混有部分有机成因气和(或)壳源无机气。中国东部已发现的36个无机成因CO2气田(藏)在空间分布上与新近纪及第四纪北西西向玄武岩活动带展布一致,深大断裂和岩浆活动是无机成因CO2富集、运移和分布最重要、最直接的两大主控因素。  相似文献   

6.
论大气微量气体增加的环境效应及地质记录研究   总被引:5,自引:0,他引:5       下载免费PDF全文
万国江 《第四纪研究》1991,11(2):158-164
大气CO2浓度增加对陆地化学侵蚀的影响小于酸雨的影响。水土流失可能促进大气CO2浓度的增高;植被破坏又影响大气CO2的固定。虽然大气CO2的较高浓度可能促成初级生产力的提高,但海洋光合作用速率增加于环境系统不利。尽管大气微量气体可能产生温室效应,但CO2与地表升温的对应关系不清楚、增温幅度与自然脉动的关系尚需客观评定。地质记录具全息性特征。加强地质记录和现代地质过程研究是揭示大气微量气体环境效应之谜的关键;从燃料和植被两个系列着手是维护全球环境的重要途径。  相似文献   

7.
土壤温室气体昼夜变化及其环境影响因素研究   总被引:13,自引:3,他引:13       下载免费PDF全文
通过对北京东灵山草地和桦树林土壤气体CO2,N2O和CH4浓度及其排放通量的昼夜连续观测,探讨了生长季节草地和森林土壤温室气体昼夜变化及其环境影响因素。研究表明:1)土壤CO2排放通量昼高夜低,N2O排放通量有明显小时尺度波动,但昼夜变化不突出;土壤CO2和N2O浓度昼夜变化不明显,且与排放通量波动不一致;土壤是大气CH4的一个汇,相对厌氧的环境可能有利于土壤吸收CH4。2)无雨时气温昼夜变化通过影响土壤表层的气体扩散和CO2产生过程,来影响土壤CO2和N2O的地表排放通量,而对土壤10cm以下CO2和N2O的产生影响不大。小时尺度的土壤CO2和N2O浓度波动则可能还有其他影响因素或机制。3)降雨时土壤渗水引起的土壤空气对流取代气体浓度扩散成为土壤与大气空气交换的主要方式,导致土壤CO2和N2O排放通量的同步波动。降雨渗水较多时,较多的溶解氧随着雨水进入土壤内,会促进土壤CO2的生成和抑制N2O的产生。4)土壤CO2与N2O浓度存在显著的正相关关系,反映出土壤CO2和N2O有相对稳定的产率比。土壤有效碳可能是造成土壤CO2与N2O浓度正相关的主要原因,土壤空气的氧分压则可能是造成土壤CO2和N2O浓度波动不一致的重要因素。  相似文献   

8.
郭栋 《物探与化探》2008,32(3):283-287
CO2气藏由于其物理、化学性质的特殊性,CO2气勘探与烃类气既有相同又有区别,综合应用多种资料和多种技术方法是识别CO2气(层)藏的有效手段。利用区域地质分析、地球物理和地球化学勘探方法综合评价非烃气的分布,提出钻探目标,通过非烃色谱测量法和红外线CO2气体浓度测量法实现CO2气层钻井现场动态检测,利用气体色谱检测相关录井参数资料、核测井密度中子孔隙度差值综合解释CO2气层,有效地识别CO2气。主要介绍CO2气藏综合勘探技术的关键的新技术方法,如地球化学方法、录井和测井综合识别的关键技术方法等。  相似文献   

9.
云贵高原湖泊CO2的地球化学变化及其大气CO2源汇效应   总被引:3,自引:0,他引:3  
湖泊是大气CO2的源还是汇,长期以来一直都存有争议。云贵高原地区的湖泊由于受流域碳酸盐岩风化作用的影响,使这一问题就显得更特殊,也更复杂。本次研究通过化学平衡计算和气相色谱测定两种方法得到了比较一致的湖水CO2浓度结果。研究发现,在夏季强烈的光合作用消耗了湖水CO2,致使湖水中CO2浓度降低。在贵州草海、百花湖以及云南的泸沽湖、杞麓湖,表层湖水CO2分压(为便于与大气CO2比较,文中湖水CO2用分压单位表示)小于200μatm,远低于大气CO2分压,湖泊正不断地从大气中吸收CO2,从而构成大气CO2的汇。  相似文献   

10.
卫星遥感探测大气CO2浓度研究最新进展   总被引:4,自引:0,他引:4  
大气CO2是一种重要的长寿命温室气体,卫星遥感探测大气CO2浓度,可以连续地获得其全球时空分布变化情况,进而提高对大气CO2源汇分布及区域和全球碳循环的认识,进一步增强对全球气候变化的研究和预测。卫星遥感探测大气CO2浓度已经开始成为一个新的研究领域,文章综合论述了利用卫星平台遥感探测大气CO2浓度分布的最新研究状况。首先简单地叙述了现阶段对大气CO2浓度时空分布和变化情况的直接仪器观测结果,在此基础上比较全面地综述了卫星遥感测量大气CO2浓度的主要方法及获得的结果,包括利用近红外反射太阳光谱或地气热红外发射辐射光谱及两者的组合进行得模拟和卫星实测反演研究,最后简单地进行了总结和展望。  相似文献   

11.
Siyue Li  X. X. Lu 《Natural Hazards》2012,62(3):1343-1345
Anthropogenic greenhouse gas (GHG) emissions have substantially contributed to intensification of heavy precipitation and thus the risk of flood occurrence, and this anthropogenic climate change is now likely to continue for many centuries. Thus, precise quantification of human-induced GHG emissions is urgently required for modeling future global warming and precipitation changes, which is strongly linked to flood disasters. Recently, GHG evasion from hydroelectric reservoirs was estimated to be 48 Tg C as CO2 and 3 Tg C as CH4 annually, lower than earlier estimate (published in Nature Geoscience; 2011). Here, we analyzed the uncertainties of GHG emissions from hydroelectric reservoirs, that is, reservoir surface area, data paucity and carbon emission relating to ecological zone, and argued that GHG evasion from global hydroelectric reservoirs has been largely under-estimated. Our study hopes to improve the quantification for future researches.  相似文献   

12.
A field control experiment was carried out to determine the influence of water table changes on soil CO2, CH4, and N2O emissions in Calamagrostis angustifolia freshwater marsh in Northeast of China. The results showed that the water depth of 5 cm below the ground surface increased soil CO2 emission, but there was no significant influence of deeper water table on gas emission. CH4 emission was accelerated by deep standing water and approached the peak in the plant booming time. This suggests that root activity has influence on CH4 production. The result also demonstrated that both low water table level and inundated environment would inhibit N2O emission. Comparing the total global warming potential of three gases under different conditions, it can be concluded that maintaining a comparatively steady water table near the soil surface can benefit soil carbon sequestration in the C. angustifolia marsh, and decrease of the greenhouse gases emissions to the atmosphere.  相似文献   

13.
Measuring fluxes of greenhouse gases (GHGs) is fundamental to estimating their impact on global warming. We examined diurnal variations of carbon dioxide (CO2), methane (CH4), and nitrous oxide (N2O) vertical fluxes in a tidal marsh ecosystem. Measurements were recorded on neap and spring tide days in April and September 2010 in the Shanyutan wetland of the Min River estuary, southeast China. Here, we define a positive flux as directing into the atmosphere. CH4 fluxes on the diurnal scale were positive throughout, and CH4 emissions into the atmosphere on neap tide days were higher than on spring tide days. CH4 releases from the marsh ecosystem on neap tide days were higher in the daytime; however, on spring tide days, daily variations of CH4 emissions were more complex. The marsh ecosystem plays a twofold role in both releasing and assimilating CO2 and N2O gases on the diurnal scale. Average CO2 fluxes were positive on the daily scale both on neap and spring days and were greater on the neap tide days than on spring tide days. Diurnal variations of N2O fluxes fluctuated more. Over the diurnal period, soil temperature markedly controlled variations of CH4 emissions compared to other soil factors, such as salinity and redox potential. Tidal water height was a key factor influencing GHGs fluxes at the water–air interface. Compared with N2O, the diurnal course of CO2 and CH4 fluxes in the marsh ecosystem appeared to be directly controlled by marsh plants. These results have implications for sampling and scaling strategies for estimating GHGs fluxes in tidal marsh ecosystems.  相似文献   

14.
表层岩溶生态系统碳循环特征研究   总被引:32,自引:3,他引:29       下载免费PDF全文
本文以广西桂林丫吉试验场的实际观测资料为基础,应用同位素示踪方法,探索了整个系统中碳的输入、输出和转移问题,并分析了表层岩溶生态系统中泉水水化学、土壤 CO2浓度及近地表植被层空气中CO2浓度的变化特征。结果显示,泉水水化学主要组分的日变化不明显,而土壤中CO2浓度则明显受日气候变化的影响,两者存在明显的滞后关系。用碳同位素示踪方法,重点对桂林观测站表层生态系统各碳库间碳的转移过程进行了定量研究,认为在有土壤层和植被覆盖的表层岩溶生态系统中,参与岩溶作用的碳有一半以上来源于与生物作用有关的碳。  相似文献   

15.
This study investigates the occurrence of greenhouse gases (GHGs) and the role of groundwater as an indirect pathway of GHG emissions into surface waters in a gaining stretch of the Triffoy River agricultural catchment (Belgium). To this end, nitrous oxide (N2O), methane (CH4) and carbon dioxide (CO2) concentrations, the stable isotopes of nitrate, and major ions were monitored in river and groundwater over 8 months. Results indicated that groundwater was strongly oversaturated in N2O and CO2 with respect to atmospheric equilibrium (50.1 vs. 0.55 μg L?1 for N2O and 14,569 vs. 400 ppm for CO2), but only marginally for CH4 (0.45 vs. 0.056 μg L?1), suggesting that groundwater can be a source of these GHGs to the atmosphere. Nitrification seemed to be the main process for the accumulation of N2O in groundwater. Oxic conditions prevailing in the aquifer were not prone for the accumulation of CH4. In fact, the emissions of CH4 from the river were one to two orders of magnitude higher than the inputs from groundwater, meaning that CH4 emissions from the river were due to CH4 in-situ production in riverbed or riparian zone sediments. For CO2 and N2O, average emissions from groundwater were 1.5?×?105 kg CO2 ha?1 year?1 and 207 kg N2O ha?1 year?1, respectively. Groundwater is probably an important source of N2O and CO2 in gaining streams but when the measures are scaled at catchment scale, these fluxes are probably relatively modest. Nevertheless, their quantification would better constrain nitrogen and carbon budgets in natural systems.  相似文献   

16.
The importance of mitigation of climate change due to greenhouse gas (GHG) emissions from various developmental and infrastructure projects has generated interest at global level to reduce environmental impacts. Life cycle assessment may be used as a tool to assess GHG emissions and subsequent environmental impacts resulting from electricity generation from thermal power plants. This study uses life cycle approach for assessing GHG emissions and their impacts due to natural gas combined cycle (NGCC) and imported coal thermal power plants using the IPCC 2001 and Eco-Indicator 99(H) methods in India for the first time. The total GHG emission from the NGCC thermal power plant was 584 g CO2 eq/kWh electricity generation, whereas in case of imported coal, it was 1,127 g CO2 eq/kWh electricity generation. This shows that imported coal has nearly ~2 times more impacts when compared to natural gas in terms of global warming potential and human health as disability-adjusted life years from climate change due to GHG emissions such as carbon dioxide (CO2), methane (CH4) and nitrous oxide (N2O).  相似文献   

17.
Soils act as sources and sinks for greenhouse gases (GHG) such as carbon dioxide (CO2), methane (CH4), and nitrous oxide (N2O). Since both storage and emission capacities may be large, precise quantifications are needed to obtain reliable global budgets that are necessary for land-use management (agriculture, forestry), global change and for climate research. This paper discusses exclusively the soil emission-related processes and their influencing parameters. It reviews soil emission studies involving the most important land-cover types and climate zones and introduces important measuring systems for soil emissions. It addresses current shortcomings and the obvious bias towards northern hemispheric data.When using a conservative average of 300 mg CO2e m−2 h−1 (based on our literature review), this leads to global annual net soil emissions of ≥350 Pg CO2e (CO2e = CO2 equivalents = total effect of all GHG normalized to CO2). This corresponds to roughly 21% of the global soil C and N pools. For comparison, 33.4 Pg CO2 are being emitted annually by fossil fuel combustion and the cement industry.  相似文献   

18.
Fluxes of nitrous oxide (N2O) from different land use patterns (matured forest, secondary forest, grassland and cropland) in a subtropical karst region of Guizhou Province, Southwest China, were measured for one year with a closed static chamber technique and by gas chromatography. The results showed that soil under different land uses was a source of atmospheric N2O. The cropland was a source with relatively high N2O as compared to forest and grassland, but no significant differences were observed. N2O emissions from soils varied with land use change and fertilizer application. There were two peaks of N2O flux occurred following the combination of two obvious precipitation and fertilizer events in the cultivated land. Converting from the matured forest to secondary forest tended to increase annual emissions of N2O (from 1.40 to 1.65 kg N ha -1 a -1 ), while changing land use from secondary forest to scattered grassland tended to decrease annual emissions of N2O slightly (from 1.65 to 1.45 kg N ha -1 a -1 ). Our range of cumulative annual N2O emission across different land uses (1.40-1.91 kg N ha -1 a -1 ) in a karst region is in general agreement with previously published data in a non-karst region. However, in the maize field, N2O emission factor (EF) was 0.34% for fertilizer application, which is about 71.2% lower than the IPCC default value. It is suggested that current IPCC (Intergovernmental Panel on Climate Change) EF methodology could overestimate N2O emission from the karstic cropland. Anyway, the N2O emission from cropland in the karst region would contribute significantly to the global N2O budget, so reducing fertilization frequency during the crop growing season could lead to a decrease in N2O emission in the whole year.  相似文献   

19.
Freshwater marshes could be a source of greenhouse gases emission because they contain large amounts of soil carbon and nitrogen. These emissions are strongly influenced by exogenous nitrogen. We investigate the effects of exogenous nitrogen on ecosystem respiration (CO2), CH4 and N2O emissions from freshwater marshes in situ in the Sanjiang Plain Northeast of China during the growing seasons of 2004 and 2005, using a field fertilizer experiment and the static opaque chamber/GC techniques. The results show that there were no significant differences in patterns of seasonal variations of CO2 and CH4 among the fertilizer and non-fertilizer treatments, but the seasonal patterns of N2O emission were significantly influenced by the exogenous nitrogen. Seasonal averages of the CO2 flux from non-fertilizer and fertilizer were 987.74 and 1,344.35 mg m 2 h 1, respectively, in 2004, and 898.59 and 2,154.17 mg m 2 h 1, respectively, in 2005. And the CH4 from the control and fertilizer treatments were 6.05 and 13.56 mg m 2 h 1 and 0.72 and 1.88 mg m 2 h 1, respectively, in 2004 and 2005. The difference of N2O flux between the fertilizer and non-fertilizer treatments is also significant either in 2004 and 2005. On the time scale of 20-, 100-, and 500-year periods, the integrated global warming potential (GWP) of CO2 + CH4 + N2O released during the two growing seasons for the treatment of fertilizer was 97, 94 and 89%, respectively, higher than that for the control, which suggested that the nitrogen fertilizer can enhance the GWP of the CH4 and N2O either in long time or short time scale.  相似文献   

20.
In order to better understand the spatiotemporal variations and interrelationships of greenhouse gases (GHG), monthly surface fluxes and profile concentrations of GHG (CO2, N2O and CH4) in karst areas in the Guizhou Province, southwest China, were measured from June 2006 to May 2007. GHG fluxes showed high variability, with a range of 460.9?C1,281.2?mg?m?2?h?1 for CO2, ?25.4 to 81.5???g?m?2?h?1 for N2O and ?28.7 to ?274.9???g?m?2?h?1 for CH4, but no obvious seasonal change trends of the fluxes existed. Profile concentrations of CO2, N2O and CH4 varied between 0.5 and 31.5?mL?L?1, 0.273 and 0.734, and 0.1 and 3.5???L?L?1, respectively. In general, concentrations of CO2 and N2O increased with depth, while CH4 had an inverse trend. However, in October, November and January, the reversal of depth patterns of GHG concentrations took place below 15?cm, close to the soil?Crock interface. The spatiotemporal distribution of CO2 in soil profile was significantly positively correlated with that of N2O (p?<?0.05?C0.01) and negatively correlated with that of CH4 (p?<?0.01). The correlation analysis showed that soil temperature and moisture may be responsible for GHG dynamics in the soils, rather than the exchange of GHG between land and atmosphere.  相似文献   

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