850 resultados para Global change and terrestrial ecosystems
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Geological, geophysical, and geochemical data support a theory that Earth experienced several intervals of intense, global glaciation (“snowball Earth” conditions) during Precambrian time. This snowball model predicts that postglacial, greenhouse-induced warming would lead to the deposition of banded iron formations and cap carbonates. Although global glaciation would have drastically curtailed biological productivity, melting of the oceanic ice would also have induced a cyanobacterial bloom, leading to an oxygen spike in the euphotic zone and to the oxidative precipitation of iron and manganese. A Paleoproterozoic snowball Earth at 2.4 Giga-annum before present (Ga) immediately precedes the Kalahari Manganese Field in southern Africa, suggesting that this rapid and massive change in global climate was responsible for its deposition. As large quantities of O2 are needed to precipitate this Mn, photosystem II and oxygen radical protection mechanisms must have evolved before 2.4 Ga. This geochemical event may have triggered a compensatory evolutionary branching in the Fe/Mn superoxide dismutase enzyme, providing a Paleoproterozoic calibration point for studies of molecular evolution.
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作为西部大开发的关键地区,西北干旱区由于地理位置和环境条件的独特性、生态系统的脆弱性以及人类活动的长期干扰,对其周边乃至全国的生态环境有较大的影响,在这一地区研究植物种分布与气候的关系,并模拟预测其可能的潜在分布范围,具有理论上和实践上的重要意义。 通过广泛收集了西北干旱区优势种和常见种的地理分布资料,共选择128个植物种,利用Holdridge的生命地带分类系统,计算各植物种的生物温度(BT)、可能蒸散(PE)、降水量(P)及可能蒸散率(PER),分析植物种与气候的相互关系,并将所有植物种进行经验归纳分类。随后,对这砦植物种及其气候信息进行TWINSPAN定量分类,并与经验分类结果相比较,得出西北干旱区128种植物的生态气候分类,分属于以下几大类型:高寒草甸、森林一草原过渡带、草原(典型草原、荒漠草原)、荒漠(草原化荒漠、荒漠、高寒荒漠)。具体来说,包括以下17个生态气候类型: 1)高寒草甸:异针茅。 2)森林一草原过渡带:牛尾蒿、鬼箭锦鸡儿、沙棘。 3)草原a:沙蒿。 4)草原b:长芒草、百里香(变种)、多叶隐子草、贝加尔针茅、大针茅。 5)草原c:羊茅、小叶锦鸡儿、荒漠锦鸡儿、线叶菊、华北岩黄芪、廿青针茅、碱蒿、内蒙古沙蒿、裂叶蒿、狭叶锦鸡儿、山竹岩黄芪、女蒿、小蓬、两伯利亚杏、沙地柏、角果碱篷、霸王、糙隐子草。 6)草原d:紫狐茅、紫花针茅。 7)草原一荒漠草原a:包括沙竹、琵琶柴、吉尔吉斯针茅。 8)草原一荒漠草原b:华北米蒿、差巴嘎蒿、星星草、长芒针茅、铁竿蒿、柠条锦鸡儿。 9)荒漠草原:沙生冰草、蒙古冰草、羊草、冷蒿、中亚紫菀木、刺旋花、老瓜头、木贼麻黄、西伯利亚白刺、唐古特白刺、戈壁针茅、石生针茅、盐地碱蓬、冰草、蓍状亚菊、油蒿、木蓼、刺针枝蓼、长枝木蓼、中间锦鸡儿、尖叶盐爪爪、黄花琵琶柴、松叶猪毛菜、珍珠猪毛菜、东方针茅、囊果碱蓬、四合木、白滨藜、短脚锦鸡儿。 10)草原化荒漠,荒漠a:川青锦鸡儿、优若藜、苦艾蒿、无芒隐子草、沙冬青、籽蒿、地白蒿、菭草、齿叶白刺、绵刺、盐角草、多枝柽柳、盐生假木贼。 11)草原化荒漠.荒漠b:蒿叶猪毛菜、短花针茅、芨芨草、灌木亚菊、博乐蒿、小蒿、喀什蒿、南山短花菊、盐爪爪、木本猪毛菜、针茅、细枝盐爪爪。 12)草原化荒漠.荒漠c:白梭梭、白羊草、无叶假木贼。 13)干旱荒漠a:戈壁短花菊、荒漠细柄茅、刺蓬、沙生针茅、多花柽柳、细枝柽柳。 14)干旱荒漠b:梭梭柴、铃铛刺、天山猪毛菜、帕米尔麻黄、座花针茅、旱蒿、克氏狐茅、短叶假木贼、准格尔沙蒿、长穗柽柳、刚毛柽柳。 15)高寒荒漠植被:匍生优若藜。 16)干旱荒漠c:粉花蒿、白杆沙拐枣、膜果麻黄、花花柴、灌木紫菀木、裸果木、合头草、塔里木沙拐枣。 17)超干旱荒漠植被:沙拐枣、胡杨、盐穗木、灰杨、盐节木、圆叶盐爪爪。 综合分类结果表明:多数植物种的生态气候类型与实际生境相符,但也有少数植物种有明显偏差,主要原因有三点:首先,某些种的分布范围超出了西北干旱区,在东北、华北、甚至全国范围内分布,所计算的植物种的气候范围本身存在局限性;其次,西北干旱区的研究资料如植物种的分布范围、分布点的气象资料等有许多缺失:最后,由于文献中对某些植物种分布范围的描述比较笼统,无法确定其精确的地理分布界限,使得植物种所对应的分类结果与其真正所属的植 被类型有一些偏差。 本文还进一步在这128种植物中选取了10种分布明确、资料齐备的代表性植被类型的优势种,根据它们的降水和生物温度指标,模拟预测了它们的可能潜在分布区,包括其主要中心分布区和最大可能分布区,并与实际分布范围进行比较。结果表明.其潜在分布区的分布范围与实际调查所得资料所处范围基本一致,特别是中心分布区的预测图,而最大可能分布区与实际有一定误差。
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气候在大尺度上决定着植被的分布、结构和组成,植被结构和生理状态的改变可以通过改变植被的反射率、粗糙度以及水分通量进而影响气候,这样形成了气候一植被的相互作用。在植被一气候相互作用的研究中,植物功能型是重要的概念和方法,它可以在详尽描述植被生物物理和生理特征的同时,有效削减植被的复杂性。植物功能型的概念和方法已经在植物群落、生态系统的复杂性和功能、古植被和古气候研究,以及陆面过程模型和动态全球植被模型中得到了广泛的应用。但是针对我国植被-气候的相互作用和区域尺度的全球变化研究,还需要一套特定的植物功能型.生物群区体系。 本论文根据我国植被生态学和植被分类的研究背景,结合植被.气候相互作用和区域全球变化研究的需要,提出了一套适宜于中国的植物功能型.生物群区划分方案。首先,根据中国植被和气候特征,筛选并确定了影响植被生物物理和生理属性以及植被分布的6个关键的植物功能特征:然后,根据这6个特征,对植物进行功能型划分,得到了29类植物功能型:再根据我国植被的实际情况和研究需要,选定了其中的18类作为我国的植物功能型。这套功能型包括了7类‘树’功能型,6类‘灌木’功能型和5类‘草’功能型,其中含有4类高寒植物功能型,专门用于描述青藏高原的植被分布,并根据需要设置了2类‘裸地,功能型。 根据我国气候一植被分布定量关系的相关研究以及BIOME1和Box体系的研究结果,选定7个环境变量作为限制我国植物功能型分布的关键气候因子:最冷月平均气温、最暖月平均气温、大于50C的有效生长积温、大于OºC的有效生长积温、Priestley-Taylor系数(实际蒸散与潜在蒸散的比值)、降水量、最暖月和最冷月平均气温之差。采用半峰宽法初步确定每个植物功能型的环境限定因子取值范围。并根据这套植物功能型及其环境参数建立了适宜于我国的生物群区体系,从而得到了我国的植物功能型-生物群区体系(the Chinese Plant functional Types and Biomes,CNPB)。 为了验证这套植物功能型-生物群区体系,将BIOME1和中国的植物功能型生物群区体系(CNPB)对中国植被在当前气候条件和未来气候情景下分布的模拟结果进行了比较。结果表明,这套体系可以更有效地模拟中国植被在当前和未来气候条件下的分布,特别是对青藏高原植被描述的详细程度有实质性的提高。
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Relationship between biology and environment is always the theme of ecology. Transect is becoming one of the important methods in studies on relationship between global change and terrestrial ecosystems, especially for analysis of its driving factors. Inner Mongolia Grassland is the most important in China Grassland Transect brought forward by Yu GR. In this study, changes in grassland community biomass along gradients of weather conditions in Inner Mongolia was researched by the method of transect. Methods of regression about biomass were also compared. The transect was set from Eerguna county to Alashan county (38° 07' 35" ~50° 12' 20" N, 101° 55' 25" -120° 20' 46" E) in Inner Mongolia, China. The sample sites were mainly chosen along the gradient of grassland type, meadow steppe-* typical steppe-*desert steppe-*steppification desert-^desert. The study was carried out when grassland community biomass got the peak in August or September, 2003 and 2004. And data of 49 sample sites was gotten, which included biomass, mean annual temperature, annual precipitation, accumulated temperature above zero, annual hours of sunshine and other statistical and descriptive data. The aboveground biomass was harvested, and the belowground biomass was obtained by coring (30 cm deep). Then all the biomass samples were dried within (80 + 5) °C in oven and weighted. The conclusion is as follows: 1) From the northeast to the southwest in Inner Mongolia, along the gradient of grassland type, meadow steppe-*typical steppe-*desert steppe-*steppification desert-* desert, the cover degree of vegetation community reduces. 2) By unitary regression analysis, biomass is negatively correlated with mean annual temperature, s^CTC accumulated temperature, ^10°C accumulated temperature and annual hours of sunshine, among which mean annual temperature is crucial, and positively with mean annual precipitation and mean annual relative humidity, and the correlation coefficient between biomass and mean annual relative humidity is higher. Altitude doesn't act on it evidently. Result of multiple regression analysis indicates that as the primary restrictive factor, precipitation affects biomass through complicated way on large scale, and its impaction is certainly important. Along the gradient of grassland type, total biomass reduces. The proportion of aboveground biomass to total biomass reduces and then increases after desert steppe. The trend of below ground biomass's proportion to total biomass is adverse to that of aboveground biomass. 3) Precipitation is not always the only driving factor along the transect for below-/aboveground biomass ratio of different vegetation type composed by different species, and distribution of temperature and precipitation is more important, which is much different among climatic regions, so that the trend of below-/aboveground biomass ratio along the grassland transect may change much through the circumscription of semiarid region and arid region. 4) Among reproductive allocation of aboveground biomass, only the proportion of stem in total biomass notably correlates to the given parameters. Stem/leaf biomass ratio decreases when longitude and latitude increase, caloric variables decrease, and variables about water increase from desert to meadow steppe. The change trends are good modeled by logarithm or binomial equations. 5) 0'-10 cm belowground biomass highly correlates to environmental parameters, whose proportion to total biomass changes most distinctly and increases along the gradient from the west to the east. The deeper belowground biomass responses to the environmental change on the adverse trend but not so sensitively as the surface layer. Because the change value of 0~10 cm belowground biomass is always more than that of below 10 cm along the gradient, the deference between them is balanced by aboveground biomass's change by the resource allocation equilibrium hypothesis.
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About this book: Over 100 authors present 25 contributions on the impacts of global change on terrestrial ecosystems including:key processes of the earth system such as the CO2 fertilization effect, shifts in disturbances and biome distribution, the saturation of the terrestrial carbon sink, and changes in functional biodiversity,ecosystem services such the production of wheat, pest control, and carbon storage in croplands, and sensitive regions in the world threaten by rapid changes in climate and land use such as high latitudes ecosystems, tropical forest in Southeast Asia, and ecosystems dominated by Monsoon climate.The book also explores new research developments on spatial thresholds and nonlinearities, the key role of urban development in global biogeochemical processes, and the integration of natural and social sciences to address complex problems of the human-environment system.
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The purpose of this thesis is to analyse interactions between freshwater flows, terrestrial ecosystems and human well-being. Freshwater management and policy has mainly focused on the liquid water part (surface and ground water run off) of the hydrological cycle including aquatic ecosystems. Although of great significance, this thesis shows that such a focus will not be sufficient for coping with freshwater related social-ecological vulnerability. The thesis illustrates that the terrestrial component of the hydrological cycle, reflected in vapour flows (or evapotranspiration), serves multiple functions in the human life-support system. A broader understanding of the interactions between terrestrial systems and freshwater flows is particularly important in light of present widespread land cover change in terrestrial ecosystems. The water vapour flows from continental ecosystems were quantified at a global scale in Paper I of the thesis. It was estimated that in order to sustain the majority of global terrestrial ecosystem services on which humanity depends, an annual water vapour flow of 63 000 km3/yr is needed, including 6800 km3/yr for crop production. In comparison, the annual human withdrawal of liquid water amounts to roughly 4000 km3/yr. A potential conflict between freshwater for future food production and for terrestrial ecosystem services was identified. Human redistribution of water vapour flows as a consequence of long-term land cover change was addressed at both continental (Australia) (Paper II) and global scales (Paper III). It was estimated that the annual vapour flow had decreased by 10% in Australia during the last 200 years. This is due to a decrease in woody vegetation for agricultural production. The reduction in vapour flows has caused severe problems with salinity of soils and rivers. The human-induced alteration of vapour flows was estimated at more than 15 times the volume of human-induced change in liquid water (Paper II).
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Forests play a critical role in addressing climate change concerns in the broader context of global change and sustainable development. Forests are linked to climate change in three ways. i) Forests are a source of greenhouse gas (GHG) emissions: ii) Forests offer mitigation opportunities to stabilise GHG concentrations: iii) Forests are impacted by climate change. This paper reviews studies related to climate change and forests in India: first, the studies estimating carbon inventory for the Indian land use change and forestry sector (LUCF), then the different models and mitigation potential estimates for the LUCF sector in India. Finally it reviews the studies on the impact of climate change on forest ecosystems in India, identifying the implications for net primary productivity and bio-diversity. The paper highlights data, modelling and research gaps relevant to the GHG inventory, mitigation potential and vulnerability and impact assessments for the forest sector in India.
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Recent research has generally shown that a small change in the number of species in a food web can have consequences both for community structure and ecosystem processes. However 'change' is not limited to just the number of species in a community, but might include an alteration to such properties as precipitation, nutrient cycling and temperature, all of which are correlated with productivity. Here we argue that predicted scenarios of global change will result in increased plant productivity. We model three scenarios of change using simple Lotka-Volterra dynamics, which explore how a global change in productivity might affect the strength of local species interactions and detail the consequences for community and ecosystem level stability. Our results indicate that (i) at local scales the average population size of consumers may decline because of poor quality food resources, (ii) that the strength of species interactions at equilibrium may become weaker because of reduced population size, and (iii) that species populations may become more variable and may take longer to recover from environmental or anthropogenic disturbances. At local scales interaction strengths encompass such properties as feeding rates and assimilation efficiencies, and encapsulate functionatty important information with regard to ecosystem processes. Interaction strengths represent the pathways and transfer of energy through an ecosystem. We examine how such local patterns might be affected given various scenarios of 'global change' and discuss the consequences for community stability and ecosystem functioning. (C) 2004 Elsevier GmbH. All rights reserved.
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Entre el 14 i el 18 de març de 1998 es va celebrar a Barcelona la conferència Earth’s Changing Land sota la tutela dels programes internacionals Global Change in Terrestrial Ecosystems (GCTE) i Land Use and Land Cover Change (LUCC). L’objectiu principal de la trobada era presentar les darreres aportacions científiques sobre els efectes presents i previsibles del canvi global sobre els ecosistemes terrestres i la societat. Al mateix temps, es volia afavorir l’establiment de ponts de diàleg entre els professionals implicats en el canvi global
