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1.
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
2.
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
3.
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
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
4.
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
5.
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
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7.
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
8.
对采自浙江西天目山地区的3株柳杉树盘,交叉定年后,测定了3株树轮δ13C的年序列,分析了3株树轮δ13C序列中所含的共同环境变化信息。用二项式拟合法去除气候因素引起的3个δ13C序列的高频变化,得到3个低频变化序列。分析了theLowDome冰芯记录的大气CO2浓度与树轮δ13C序列低频变化趋势的关系,建立了相应的转移函数,重建了天目山地区1685年以来大气CO2浓度变化。结果表明:用3株树轮δ13C序列重建的结果有较好的一致性,并与南极冰芯的记录及前人研究结果有很好的吻合。这一结果表明用同一地区不同树木个体的树轮δ13C序列的低频变化序列可以重建出基本一致的大气CO2浓度变化历史。 相似文献
9.
论大气二氧化碳温室效应的饱和度 总被引:4,自引:0,他引:4
利用最新版本的大气分子吸收光谱资料HITRAN2000,用精确的逐线积分算法,计算了大气CO2浓度变化后产生的辐射强迫。在此基础上,研究了CO2温室效应的饱和度以及影响CO2辐射强迫的各种因子。主要结论如下:地面温度愈高,一般辐射强迫也愈大,但辐射强迫并不完全取决于地面温度,它还受大气温度廓线的强烈影响;研究的 6种模式大气中,吸收带重叠对热带大气的CO2辐射强迫影响最大,对亚极冬季大气的影响最小;与长波辐射强迫相比,短波辐射强迫的贡献很小;CO2的温室效应在15μm带中心等波段确实已经达到饱和,但在其它(15μm带两翼,10μm,5.2μm带等)波段远未达到饱和,在最近的将来也不会达到饱和。 相似文献
10.
冰期海洋生产率的增高可能为降低冰期大气CO2分压起了很大的作用。主要有三个因素促进了海洋生产率的提高:(1)强的风力作用使赤道洋流和沿岸上升流加强;(2)上升水体营养成分的增加,反过来,这又要受全球营养物质重新分配的机制控制;(3)来源于陆地的、携带营养物质的河水和(或)粉尘的增加。海洋高生产率对降低大气CO2浓度 相似文献
11.
Most modelling endeavours concerning the CO2-climate problem address only the question of the climatic response to increasing atmospheric carbon dioxide, while the amounts of other atmospheric gases remain fixed. But associated changes, either climatologically or anthropogenically induced, of minor atmospheric constituents can also be of significance in producing a substantial global warming. We have analysed the climatic response to changes in a number of atmospheric trace gases as they may enhance or counteract CO2-induced warming if their abundance should change. A comparison of the increase in equilibrium global-mean surface temperature due to plausible changes in the concentration of several trace gases in the atmosphere based on our calculations with a one-dimensional radiative-convective model is presented in this paper. Our results indicate that roughly 35% of global surface warming could be due to changes in trace gases other than CO2 and water vapour. The possible climatic consequences of the ongoing anthropogenic changes in the minor constituents of the atmosphere are also discussed. 相似文献
12.
To stabilize the atmospheric concentration of greenhouse gases (GHG), a huge reduction of carbon dioxide (CO2) emissions is required. Although some people believe that this necessitates a considerable reduction in the use of fossil fuels or fuel switching, other options are available that allow the use of fossil fuels and reduce atmospheric emissions of CO2. Sequestration of CO2 from fossil fuel combustion in the subsurface could prevent the CO2 from reaching the surface for millions of years. Geological sequestration of CO2 in deep aquifers or in depleted oil and gas reservoirs is a mature technology. Despite the huge quantities of CO2 that can be sequestered in this way, this approach does not provide any economic benefit. This paper discusses a third option, which consists of injecting CO2 in deep coal seams to sequester the carbon and enhance the recovery of coalbed methane (CBM). Waste CO2 from CBM-fueled power plants could be injected into CBM reservoirs to produce more methane (CH4) for the power plant. The 2:1 coal-sorption selectivity for CO2 over CH4 supports the feasibility of operating fossil-fueled power plants without atmospheric CO2 emissions. Other CO2 sequestration technologies, such as ocean disposal and biofixation, are briefly discussed and the suitability of these approaches is evaluated for use in Alberta, Canada. 相似文献
13.
Abraham Lerman Michael Guidry Andreas J. Andersson Fred T. Mackenzie 《Aquatic Geochemistry》2011,17(4-5):749-773
Using coupled terrestrial and coastal zone models, we investigated the impacts of deglaciation and anthropogenic inputs on the CO2–H2O–CaCO3 system in global coastal ocean waters from the Last Glacial Maximum (LGM: 18,000 year BP) to the year 2100. With rising sea level and atmospheric CO2, the carbonate system of coastal ocean water changed significantly. We find that 6 × 1012 metric tons of carbon were emitted from the coastal ocean, growing due to the sea level rise, from the LGM to late preindustrial time (1700 AD) because of net heterotrophy and calcification processes. This carbon came to reside in the atmosphere and in the growing vegetation on land and in uptake of atmospheric CO2 through the weathering of rocks on land. It appears that carbonate accumulation, mainly, but not exclusively, in coral reefs from the LGM to late preindustrial time could account for about 24 ppmv of the 100 ppmv rise in atmospheric CO2, lending some support to the “coral reef hypothesis”. In addition, the global coastal ocean is now, or soon will be, a sink of atmospheric CO2. The temperature rise of 4–5°C since the LGM led to increased weathering rates of inorganic and organic materials on land and enhanced riverine fluxes of total C, N, and P to the coastal ocean of 68%, 108%, and 97%, respectively, from the LGM to late preindustrial time. During the Anthropocene, these trends have been exacerbated owing to rising atmospheric CO2, due to fossil fuel combustion and land-use practices, other human activities, and rising global temperatures. River fluxes of total reactive C, N, and P are projected to increase from late preindustrial time to the year 2100 by 150%, 380%, and 257%, respectively, modifying significantly the behavior of these element cycles in the coastal ocean, particularly in proximal environments. Despite the fact that the global shoal water carbonate mass has grown extensively since the LGM, the pHT (pH values on the total proton scale) of global coastal waters has decreased from ~8.35 to ~8.18 and the carbonate ion concentration declined by ~19% from the LGM to late preindustrial time. The latter represents a rate of decline of about 0.028 μmol CO3 2? per decade. In comparison, the decrease in coastal water pHT from the year 1900 to 2000 was about 8.18–8.08 and is projected to decrease further from about 8.08 to 7.85 between 2000 and 2100, according to the IS92a business-as-usual scenario of CO2 emissions. Over these 200 years, the carbonate ion concentration will fall by ~120 μmol kg?1 or 6 μmol kg?1 per decade. This decadal rate of decline of the carbonate ion concentration in the Anthropocene is 214 times the average rate of decline for the entire Holocene. Hence, when viewed against the millennial to several millennial timescale of geologic change in the coastal ocean marine carbon system, one can easily appreciate why ocean acidification is the “other CO2 problem”. 相似文献
14.
Activities to provide energy for an expanding population are increasingly disrupting and changing the concentration of atmospheric gases that increase global temperature. Increased CO2 and temperature have a clear effect on growth and production of rice as they are key factors in photosynthesis. Rice yields could be increased with increased levels of CO2, however, the rise of CO2 may be accompanied by an increase in global temperature. The effect of doubling CO2 levels on rice production was predicted using rice crop models. They showed different effects of climate change in different countries. A simulation of the Southeast Asian region indicated that a doubling of CO2 increases yield, whereas an increase in temperature decreases yield.Enhanced UV-B radiation resulting for stratographic ozone depletion has been demonstrated to significantly reduce plant height, leaf area and dry weight of two rice cultivars under glasshouse conditions. Data are still insufficient, however, for conclusive results on the effect of UV-B radiation on rice growth under field conditions.Rice production itself has a significant effect on global warming and atmospheric chemistry through methane emission from flooded ricefields. Water regime, soil properties and the rice plant are major factors controlling the flux of methane in ricefields. Global and regional estimates of methane emission rates are still highly uncertain and tentative. Integration of mechanistic modeling of methane fluxes with geographic information systems of factors controlling these processes are required to improve estimates and predictions. 相似文献
15.
We present a model of the global biogeochemical cycle of silicon (Si) that emphasizes its linkages to the carbon cycle and temperature. The Si cycle is a crucial part of global nutrient biogeochemistry regulating long-term atmospheric CO2 concentrations due to silicate mineral weathering reactions involving the uptake of atmospheric CO2 and production of riverine dissolved silica, cations and bicarbonate. In addition and importantly, the Si cycle is strongly coupled to the other nutrient cycles of N, P, and Fe; hence siliceous organisms represent a significant fraction of global primary productivity and biomass. Human perturbations involving land-use changes, burning of fossil fuel, and inorganic N and P fertilization have greatly altered the terrestrial Si cycle, changing the river discharge of Si and consequently impacting marine primary productivity primarily in coastal ocean waters. 相似文献
16.
Contribution of a sewage sludge application to the short-term carbon sequestration across a wide range of agricultural soils 总被引:1,自引:0,他引:1
José Martín Soriano-Disla J. Navarro-Pedreño I. Gómez 《Environmental Earth Sciences》2010,61(8):1613-1619
The atmospheric levels of carbon dioxide (CO2) and other greenhouse gases (GHGs) have increased dramatically since the industrial revolution. The atmospheric enrichment
with CO2 and other GHGs has resulted in multiple negative consequences: such as the increase in the average temperature and the rise
of the sea level. Hence, there is a growing interest in developing feasible methods to reduce the atmospheric levels of these
gases. One of these strategies is to enhance C sequestration through the increase of soil organic carbon (SOC) pool by the
amendment of agricultural soils with sewage sludge. However, there is considerable uncertainty about the effects (positive
or negative) of sewage sludge applications on the SOC pool. Thus, a simple approach developed under laboratory conditions
is presented to discern the effect of a single sewage sludge application of 50 t ha−1 on the short-term SOC pool in 60 contrasting agricultural soils. The role of soil factors in the C sequestration of the recently
added carbon was also studied. The application of sewage sludge supposed a mean increase of 1.7 ± 1.6 g SOC kg−1, with peak increases of up to 3.8 g SOC kg−1 and decreases of up to 4.6 g SOC kg−1. The initial SOC contents conditioned the C sequestration after sewage sludge application, and no other soil property was
related. 相似文献
17.
中国农田的温室气体排放 总被引:70,自引:2,他引:70
李长生 肖向明 S.Frolking B·Moore Ⅲ W.Salas 邱建军 张宇 庄亚辉 王效科 戴昭华 刘纪远 秦小光 廖柏寒 R.Sass 《第四纪研究》2003,23(5):493-503
中国是一个农业大国,拥有约1.33百万平方公里的农田。这些田地的种植、翻耕、施肥、灌溉等管理措施不仅长期改变着农田生态系统中的化学元素循环,而且给全球气候变化带来影响。农业生态系统对全球变化的影响主要是通过改变3种温室气体,即二氧化碳(CO2)、甲烷(CH4)和氧化亚氮(N2O)在土壤-大气界面的交换而实现的。为了分析多种因素(如气候、土壤质地、农作物品种及各种农田经营管理措施等)对农业土壤释放CO22222222 相似文献
18.
Despite uncertainties in our understanding of early Earth volcanism and atmospheric composition, thermodynamic modelling is able to offer estimates of the global production of reactive trace species (NO, OH, SO3, Cl, Br and I) from early Earth volcanism, and thereby to shed light on processes which may have been different in Earth’s early atmosphere. Model results show that thermal decomposition of magmatic H2O, CO2 and SO2 in high-T mixtures of magmatic and atmospheric gases (at T > 1400 °C) generate high levels of reactive trace gas species. Production of these reactive trace species is insensitive to atmospheric CO2 in mixtures where the atmospheric gas is the minor component and will hence continue during periods of low atmospheric CO2. Fluxes of NO, OH, Cl, Br and I from early Earth volcanism are predicted to exceed those from modern Earth volcanism as the higher temperature of early Earth emissions compensates for lower levels of O2 in the atmosphere, compared to the modern Earth. Under certain conditions, the volcanic NO flux from early Earth volcanism is found to be comparable to other sources of reactive N such as lightning NO and photochemical HCN. This is one possible source of fixed nitrogen which may alleviate any postulated Archean nitrogen crisis. Our thermodynamic model reveals that production of SO3 (a potential precursor for near-source volcanic sulphate and hence ‘primary’ volcanic aerosol) is likely to be significantly lower from early Earth volcanism. Uncertainty in the pathway to near-source sulphate in modern volcanism (i.e., the reaction of SO3 with water or direct emission) introduces a large uncertainty into the production rate of near-source volcanic sulphate on the early Earth. 相似文献
19.
在国际古气候模拟比较计划设置的标准试验方案下,首先利用中国科学院大气物理研究所的全球大气环流模式(IAP-AGCM)模拟了末次盛冰期东亚气候状况,然后通过4组数值敏感性试验逐一模拟了大气CO2浓度、海洋表面温度(SST)和海冰、陆地冰盖和地形、东亚植被变化4项强迫因子的单独气候效应,进而对末次盛冰期东亚气候的成因进行了检测。结果表明,末次盛冰期除华南局部略有升温外,中国年均地表气温显著降低,降温幅度总体上向北增大,青藏高原处存在一个降温中心。其中,SST和海冰变化是华南局部略偏暖的主因,它同时导致了东亚其他区域地表气温的显著降低,特别是在东北亚地区;陆地冰盖和地形变化对于东亚地表气温的显著冷却作用主要体现在东亚的西北部;大气CO2浓度降低会引起东亚地区0.2~0.9℃的普遍降温;相对而言,东亚植被的降温作用(0.5~1.0℃)主要显现在中国40°N以南的区域。与此同时,SST和海冰变化能引起中国东部年均降水一定程度的减少,而大气CO2浓度、陆地冰盖和地形、东亚植被单独变化均不会显著影响东亚年均降水的分布状况,然而,上述四项因子的共同变化会通过协同作用引起中国东部年均降水的显著减少,西部地区降水则与现在差别不大。此外,末次盛冰期东亚夏季风的显著减弱源于SST和海冰变化,冬季风变化则可归因于SST和海冰、陆地冰盖和地形的变化。 相似文献