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1.
Climate change is identified as a major threat to wetlands. Altered hydrology and rising temperature can change the biogeochemistry and function of a wetland to the degree that some important services might be turned into disservices. This means that they will, for example, no longer provide a water purification service and adversely they may start to decompose and release nutrients to the surface water. Moreover, a higher rate of decomposition than primary production (photosynthesis) may lead to a shift of their function from being a sink of carbon to a source. This review paper assesses the potential response of natural wetlands (peatlands) and constructed wetlands to climate change in terms of gas emission and nutrients release. In addition, the impact of key climatic factors such as temperature and water availability on wetlands has been reviewed. The authors identified the methodological gaps and weaknesses in the literature and then introduced a new framework for conducting a comprehensive mesocosm experiment to address the existing gaps in literature to support future climate change research on wetland ecosystems. In the future, higher temperatures resulting in drought might shift the role of both constructed wetland and peatland from a sink to a source of carbon. However, higher temperatures accompanied by more precipitation can promote photosynthesis to a degree that might exceed the respiration and maintain the carbon sink role of the wetland. There might be a critical water level at which the wetland can preserve most of its services. In order to find that level, a study of the key factors of climate change and their interactions using an appropriate experimental method is necessary. Some contradictory results of past experiments can be associated with different methodologies, designs, time periods, climates, and natural variability. Hence a long-term simulation of climate change for wetlands according to the proposed framework is recommended. This framework provides relatively more accurate and realistic simulations, valid comparative results, comprehensive understanding and supports coordination between researchers. This can help to find a sustainable management strategy for wetlands to be resilient to climate change. 相似文献
2.
Climate change is identified as a major threat to wetlands. Altered hydrology and rising temperature can change the biogeochemistry and function of a wetland to the degree that some important services might be turned into disservices. This means that they will, for example, no longer provide a water purification service and adversely they may start to decompose and release nutrients to the surface water. Moreover, a higher rate of decomposition than primary production (photosynthesis) may lead to a shift of their function from being a sink of carbon to a source. This review paper assesses the potential response of natural wetlands (peatlands) and constructed wetlands to climate change in terms of gas emission and nutrients release. In addition, the impact of key climatic factors such as temperature and water availability on wetlands has been reviewed. The authors identified the methodological gaps and weaknesses in the literature and then introduced a new framework for conducting a comprehensive mesocosm experiment to address the existing gaps in literature to support future climate change research on wetland ecosystems. In the future, higher temperatures resulting in drought might shift the role of both constructed wetland and peatland from a sink to a source of carbon. However, higher temperatures accompanied by more precipitation can promote photosynthesis to a degree that might exceed the respiration and maintain the carbon sink role of the wetland. There might be a critical water level at which the wetland can preserve most of its services. In order to find that level, a study of the key factors of climate change and their interactions using an appropriate experimental method is necessary. Some contradictory results of past experiments can be associated with different methodologies, designs, time periods, climates, and natural variability. Hence a long-term simulation of climate change for wetlands according to the proposed framework is recommended. This framework provides relatively more accurate and realistic simulations, valid comparative results, comprehensive understanding and supports coordination between researchers. This can help to find a sustainable management strategy for wetlands to be resilient to climate change. 相似文献
3.
Climate change is identified as a major threat to wetlands. Altered hydrology and rising temperature can change the biogeochemistry and function of a wetland to the degree that some important services might be turned into disservices. This means that they will, for example, no longer provide a water purification service and adversely they may start to decompose and release nutrients to the surface water. Moreover, a higher rate of decomposition than primary production (photosynthesis) may lead to a shift of their function from being a sink of carbon to a source. This review paper assesses the potential response of natural wetlands (peatlands) and constructed wetlands to climate change in terms of gas emission and nutrients release. In addition, the impact of key climatic factors such as temperature and water availability on wetlands has been reviewed. The authors identified the methodological gaps and weaknesses in the literature and then introduced a new framework for conducting a comprehensive mesocosm experiment to address the existing gaps in literature to support future climate change research on wetland ecosystems. In the future, higher temperatures resulting in drought might shift the role of both constructed wetland and peatland from a sink to a source of carbon. However, higher temperatures accompanied by more precipitation can promote photosynthesis to a degree that might exceed the respiration and maintain the carbon sink role of the wetland. There might be a critical water level at which the wetland can preserve most of its services. In order to find that level, a study of the key factors of climate change and their interactions using an appropriate experimental method is necessary. Some contradictory results of past experiments can be associated with different methodologies, designs, time periods, climates, and natural variability. Hence a long-term simulation of climate change for wetlands according to the proposed framework is recommended. This framework provides relatively more accurate and realistic simulations, valid comparative results, comprehensive understanding and supports coordination between researchers. This can help to find a sustainable management strategy for wetlands to be resilient to climate change. 相似文献
4.
Climate change is identified as a major threat to wetlands. Altered hydrology and rising temperature can change the biogeochemistry and function of a wetland to the degree that some important services might be turned into disservices. This means that they will, for example, no longer provide a water purification service and adversely they may start to decompose and release nutrients to the surface water. Moreover, a higher rate of decomposition than primary production (photosynthesis) may lead to a shift of their function from being a sink of carbon to a source. This review paper assesses the potential response of natural wetlands (peatlands) and constructed wetlands to climate change in terms of gas emission and nutrients release. In addition, the impact of key climatic factors such as temperature and water availability on wetlands has been reviewed. The authors identified the methodological gaps and weaknesses in the literature and then introduced a new framework for conducting a comprehensive mesocosm experiment to address the existing gaps in literature to support future climate change research on wetland ecosystems. In the future, higher temperatures resulting in drought might shift the role of both constructed wetland and peatland from a sink to a source of carbon. However, higher temperatures accompanied by more precipitation can promote photosynthesis to a degree that might exceed the respiration and maintain the carbon sink role of the wetland. There might be a critical water level at which the wetland can preserve most of its services. In order to find that level, a study of the key factors of climate change and their interactions using an appropriate experimental method is necessary. Some contradictory results of past experiments can be associated with different methodologies, designs, time periods, climates, and natural variability. Hence a long-term simulation of climate change for wetlands according to the proposed framework is recommended. This framework provides relatively more accurate and realistic simulations, valid comparative results, comprehensive understanding and supports coordination between researchers. This can help to find a sustainable management strategy for wetlands to be resilient to climate change. 相似文献
5.
Climate change is identified as a major threat to wetlands. Altered hydrology and rising temperature can change the biogeochemistry and function of a wetland to the degree that some important services might be turned into disservices. This means that they will, for example, no longer provide a water purification service and adversely they may start to decompose and release nutrients to the surface water. Moreover, a higher rate of decomposition than primary production (photosynthesis) may lead to a shift of their function from being a sink of carbon to a source. This review paper assesses the potential response of natural wetlands (peatlands) and constructed wetlands to climate change in terms of gas emission and nutrients release. In addition, the impact of key climatic factors such as temperature and water availability on wetlands has been reviewed. The authors identified the methodological gaps and weaknesses in the literature and then introduced a new framework for conducting a comprehensive mesocosm experiment to address the existing gaps in literature to support future climate change research on wetland ecosystems. In the future, higher temperatures resulting in drought might shift the role of both constructed wetland and peatland from a sink to a source of carbon. However, higher temperatures accompanied by more precipitation can promote photosynthesis to a degree that might exceed the respiration and maintain the carbon sink role of the wetland. There might be a critical water level at which the wetland can preserve most of its services. In order to find that level, a study of the key factors of climate change and their interactions using an appropriate experimental method is necessary. Some contradictory results of past experiments can be associated with different methodologies, designs, time periods, climates, and natural variability. Hence a long-term simulation of climate change for wetlands according to the proposed framework is recommended. This framework provides relatively more accurate and realistic simulations, valid comparative results, comprehensive understanding and supports coordination between researchers. This can help to find a sustainable management strategy for wetlands to be resilient to climate change. 相似文献
6.
Climate change is identified as a major threat to wetlands. Altered hydrology and rising temperature can change the biogeochemistry and function of a wetland to the degree that some important services might be turned into disservices. This means that they will, for example, no longer provide a water purification service and adversely they may start to decompose and release nutrients to the surface water. Moreover, a higher rate of decomposition than primary production (photosynthesis) may lead to a shift of their function from being a sink of carbon to a source. This review paper assesses the potential response of natural wetlands (peatlands) and constructed wetlands to climate change in terms of gas emission and nutrients release. In addition, the impact of key climatic factors such as temperature and water availability on wetlands has been reviewed. The authors identified the methodological gaps and weaknesses in the literature and then introduced a new framework for conducting a comprehensive mesocosm experiment to address the existing gaps in literature to support future climate change research on wetland ecosystems. In the future, higher temperatures resulting in drought might shift the role of both constructed wetland and peatland from a sink to a source of carbon. However, higher temperatures accompanied by more precipitation can promote photosynthesis to a degree that might exceed the respiration and maintain the carbon sink role of the wetland. There might be a critical water level at which the wetland can preserve most of its services. In order to find that level, a study of the key factors of climate change and their interactions using an appropriate experimental method is necessary. Some contradictory results of past experiments can be associated with different methodologies, designs, time periods, climates, and natural variability. Hence a long-term simulation of climate change for wetlands according to the proposed framework is recommended. This framework provides relatively more accurate and realistic simulations, valid comparative results, comprehensive understanding and supports coordination between researchers. This can help to find a sustainable management strategy for wetlands to be resilient to climate change. 相似文献
7.
Climate change is identified as a major threat to wetlands. Altered hydrology and rising temperature can change the biogeochemistry and function of a wetland to the degree that some important services might be turned into disservices. This means that they will, for example, no longer provide a water purification service and adversely they may start to decompose and release nutrients to the surface water. Moreover, a higher rate of decomposition than primary production (photosynthesis) may lead to a shift of their function from being a sink of carbon to a source. This review paper assesses the potential response of natural wetlands (peatlands) and constructed wetlands to climate change in terms of gas emission and nutrients release. In addition, the impact of key climatic factors such as temperature and water availability on wetlands has been reviewed. The authors identified the methodological gaps and weaknesses in the literature and then introduced a new framework for conducting a comprehensive mesocosm experiment to address the existing gaps in literature to support future climate change research on wetland ecosystems. In the future, higher temperatures resulting in drought might shift the role of both constructed wetland and peatland from a sink to a source of carbon. However, higher temperatures accompanied by more precipitation can promote photosynthesis to a degree that might exceed the respiration and maintain the carbon sink role of the wetland. There might be a critical water level at which the wetland can preserve most of its services. In order to find that level, a study of the key factors of climate change and their interactions using an appropriate experimental method is necessary. Some contradictory results of past experiments can be associated with different methodologies, designs, time periods, climates, and natural variability. Hence a long-term simulation of climate change for wetlands according to the proposed framework is recommended. This framework provides relatively more accurate and realistic simulations, valid comparative results, comprehensive understanding and supports coordination between researchers. This can help to find a sustainable management strategy for wetlands to be resilient to climate change. 相似文献
8.
Climate change is identified as a major threat to wetlands. Altered hydrology and rising temperature can change the biogeochemistry and function of a wetland to the degree that some important services might be turned into disservices. This means that they will, for example, no longer provide a water purification service and adversely they may start to decompose and release nutrients to the surface water. Moreover, a higher rate of decomposition than primary production (photosynthesis) may lead to a shift of their function from being a sink of carbon to a source. This review paper assesses the potential response of natural wetlands (peatlands) and constructed wetlands to climate change in terms of gas emission and nutrients release. In addition, the impact of key climatic factors such as temperature and water availability on wetlands has been reviewed. The authors identified the methodological gaps and weaknesses in the literature and then introduced a new framework for conducting a comprehensive mesocosm experiment to address the existing gaps in literature to support future climate change research on wetland ecosystems. In the future, higher temperatures resulting in drought might shift the role of both constructed wetland and peatland from a sink to a source of carbon. However, higher temperatures accompanied by more precipitation can promote photosynthesis to a degree that might exceed the respiration and maintain the carbon sink role of the wetland. There might be a critical water level at which the wetland can preserve most of its services. In order to find that level, a study of the key factors of climate change and their interactions using an appropriate experimental method is necessary. Some contradictory results of past experiments can be associated with different methodologies, designs, time periods, climates, and natural variability. Hence a long-term simulation of climate change for wetlands according to the proposed framework is recommended. This framework provides relatively more accurate and realistic simulations, valid comparative results, comprehensive understanding and supports coordination between researchers. This can help to find a sustainable management strategy for wetlands to be resilient to climate change. 相似文献
9.
湿地是流域水循环和水量平衡的重要调节器,在维护流域水量平衡、减轻洪旱灾害和应对气候变化等方面发挥极其重要的作用。流域湿地水文调蓄功能是湿地生态水文学研究的重要内容,科学认识和理解流域湿地水文调蓄功能对流域湿地恢复保护、水资源综合管控与应对气候变化具有极其重要的意义。本文阐述了流域湿地水文调蓄功能的概念与内涵,剖析了流域湿地水文调蓄功能时空变异性、阈值性和多维性三大特征及其影响因素(包括湿地土壤特性、植被特征和初始水文条件等内在因素和流域特征、降雨特征、气候变化和人类活动等外在因素),探讨了流域湿地不变情景下和变化情景下水文调蓄功能评估方法,并介绍了流域湿地水文调蓄功能定量评估模型与应用情况。最后,从学科发展和实践需求的视角提出了流域湿地水文调蓄功能未来亟需加强研究的重点方向。 相似文献
10.
John W. Day Robert R. Christian Donald M. Boesch Alejandro Yáñez-Arancibia James Morris Robert R. Twilley Larissa Naylor Linda Schaffner Court Stevenson 《Estuaries and Coasts》2008,31(3):477-491
Climate impacts on coastal and estuarine systems take many forms and are dependent on the local conditions, including those
set by humans. We use a biocomplexity framework to provide a perspective of the consequences of climate change for coastal
wetland ecogeomorphology. We concentrate on three dimensions of climate change affects on ecogeomorphology: sea level rise,
changes in storm frequency and intensity, and changes in freshwater, sediment, and nutrient inputs. While sea level rise,
storms, sedimentation, and changing freshwater input can directly impact coastal and estuarine wetlands, biological processes
can modify these physical impacts. Geomorphological changes to coastal and estuarine ecosystems can induce complex outcomes
for the biota that are not themselves intuitively obvious because they are mediated by networks of biological interactions.
Human impacts on wetlands occur at all scales. At the global scale, humans are altering climate at rapid rates compared to
the historical and recent geological record. Climate change can disrupt ecological systems if it occurs at characteristic
time scales shorter than ecological system response and causes alterations in ecological function that foster changes in structure
or alter functional interactions. Many coastal wetlands can adjust to predicted climate change, but human impacts, in combination
with climate change, will significantly affect coastal wetland ecosystems. Management for climate change must strike a balance
between that which allows pulsing of materials and energy to the ecosystems and promotes ecosystem goods and services, while
protecting human structures and activities. Science-based management depends on a multi-scale understanding of these biocomplex
wetland systems. Causation is often associated with multiple factors, considerable variability, feedbacks, and interferences.
The impacts of climate change can be detected through monitoring and assessment of historical or geological records. Attribution
can be inferred through these in conjunction with experimentation and modeling. A significant challenge to allow wise management
of coastal wetlands is to develop observing systems that act at appropriate scales to detect global climate change and its
effects in the context of the various local and smaller scale effects. 相似文献
11.
基于湿地生态水文研究文献计量分析,透视国内外有关湿地水文、生态水文和水资源等领域的重大研究计划和重要学术会议,系统总结了湿地生态水文学发展历程,可分为萌芽起步阶段(20世纪50年代至80年代)、研究探索阶段(20世纪90年代)和快速发展阶段(21世纪以后)3个阶段,列举了重要代表性研究成果,并重点阐述了湿地生态水文学研究进展;基于对国际湿地生态水文学发展历程、研究进展及热点的综合分析,未来湿地生态水文学研究主要向基于"多要素、多过程、多尺度"的湿地生态水文相互作用机理及耦合机制、气候变化对湿地生态水文的影响机理及适应性调控、湿地"水文-生态-社会"耦合系统互作机理及互馈机制和基于湿地生态需水与水文服务的流域水资源综合管理等方向发展。最后,以国家重大需求为导向,提出了未来中国湿地生态水文学优先发展方向及建议。 相似文献
12.
《Quaternary Science Reviews》2004,23(18-19):1989-2005
Interstadials during the last glacial show a rapid rise of the atmospheric methane concentration at the onset of climatic warming. This is explained by reaction of (northern) wetlands to climate change, or by catastrophic release of methane from sea floor methane clathrates. The wetland hypothesis usually assumes expansion of wetlands, which is a slow process and difficult to reconcile with the rapid rise of the atmospheric methane concentration. Here it is demonstrated by modeling that wetland methane fluxes may have reacted rapidly on climatic warming by its direct effect on methane production, without the assumption of wetland expansion. A bottom-up modeling of methane fluxes in northern Europe during Oxygen Isotope Stage 3 is presented. This study combines paleodata on wetland ecology, climate model output, a process-based methane flux model, and GIS-based modeling of wetland areal distribution. The resulting methane flux during interstadials is twice as high as during stadials. This is attributed to higher bacterial metabolic rates, a longer frost-free period, and a higher ecosystem primary production providing more substrate for methanogenesis. 相似文献
13.
Reshmi Sarkar 《Environmental Earth Sciences》2018,77(14):530
Increasing CO2 levels and its consequent effects have been prominent with climate change. Three out of ten transgressed planetary boundaries reflect our planet’s status at tipping point. Soil Organic Carbon (SOC) which helps soil supply water and nutrients to plants through roots is inherently related to various ecological systems and needs urgent attention. Although the total SOC globally is more than the total carbon in biosphere and atmosphere, the vulnerability of SOC due to anthropogenic activities is unavoidable. The environmental factors affecting sequestration of SOC, soil fertility, crop production, accelerated SOC removal with rising temperatures, green-house gases emissions and climate change are interrelated. Thus, it is impossible to understand and estimate the various scenarios of impacts on SOC pool with ever-changing ecosystems and related processes in soil environment completely. Based on currently predicted climate change scenarios, if deforestation is controlled and reestablishment is achieved, tropical forests can trap atmospheric CO2 in the cheapest way and function as the largest sink on earth. The agricultural management practices (AMPs), which have been practiced in the last two decades and found helpful are suitable. However, some innovative adaptations such as crop modelling, selecting types of residue to change microbial communities, practices of grassland-grazing and low-C-emission AMPs are also necessary. To achieve the millennium development goals, we must accomplish food security, which relates all 17 sustainable development goals (SDGs) also relays agricultural systems, soil systems, ecosystem services, soil fertility and how best we nurture SOC pool with supportive AMPs. 相似文献
14.
桂林会仙岩溶湿地典型水生植物δ13C特征与固碳量估算 总被引:4,自引:3,他引:1
为促进目前岩溶碳汇稳定性和速率等科学问题的深入研究,在分析桂林会仙岩溶湿地主要水生植物碳同位素的基础上,利用基于碳酸酐酶活性与植物碳同位素值显著正相关的二端元模型,估算了不同植物利用光合作用固定HCO3-的比例。结果表明,湿地核心区沉水植物光合作用固定HCO3-碳量在4.86~64.73 tC/(a?km2)之间,挺水植物为15.68~453.01 tC/(a?km2),平均值为76.74 tC/(a?km2)。按平均值计算会仙湿地水生植物光合作用固定HCO3-碳量为4 466.27 tC/a,即在会仙湿地岩溶地下河补给的HCO3-中约47 %被水生植物光合作用固定。水生植物光合作用固碳效果明显,是碳汇研究中不容忽视的一个十分重要的问题。 相似文献
15.
近百年来全球气候呈现以变暖为主要特征的显著变化,并且未来气温将继续上升,降水模式也会发生改变。从气候变化对湿地水文水资源的影响、气候变化影响下湿地水文与生态的相互作用过程以及湿地生态水文模型等3个方面,对国内外相关研究动态和发展趋势进行了总结分析。从中发现,当前全球气候背景下的湿地生态水文学正在从单一湿地生态水文过程为主要对象,发展成为以研究气候-水文-生态三者相互作用机制为主要内容的综合性、交叉性学科。现关于气候变化影响下水文-生态之间的关系多集中于单向作用的研究,特别是水文过程对植被的影响研究较多,缺乏对气候变化影响下湿地水文过程与生态过程相互作用机理的全面认识。气候变化对湿地生态水文的影响机制研究已经成为水文学研究亟待解决的科学问题,而基于物理机制的湿地生态水文模型,逐渐成为预测未来气候变化下湿地生态水文响应的重要工具。 相似文献
16.
John C. Callaway Evyan L. Borgnis R. Eugene Turner Charles S. Milan 《Estuaries and Coasts》2012,35(5):1163-1181
Tidal wetlands play an important role with respect to climate change because of both their sensitivity to sea-level rise and their ability to sequester carbon dioxide from the atmosphere. Policy-based interest in carbon sequestration has increased recently, and wetland restoration projects have potential for carbon credits through soil carbon sequestration. We measured sediment accretion, mineral and organic matter accumulation, and carbon sequestration rates using 137Cs and 210Pb downcore distributions at six natural tidal wetlands in the San Francisco Bay Estuary. The accretion rates were, in general, 0.2?C0.5?cm?year?1, indicating that local wetlands are keeping pace with recent rates of sea-level rise. Mineral accumulation rates were higher in salt marshes and at low-marsh stations within individual sites. The average carbon sequestration rate based on 210Pb dating was 79?g?C?m?2?year?1, with slightly higher rates based on 137Cs dating. There was little difference in the sequestration rates among sites or across stations within sites, indicating that a single carbon sequestration rate could be used for crediting tidal wetland restoration projects within the Estuary. 相似文献
17.
以贵州省施秉县黄洲河典型白云岩岩溶小流域为例,基于白云石化学平衡热力学方法分别定量估算出1990-1992年、2001-2003年及2016-2018年白云岩流域的年均岩溶碳汇强度,并分析其对气候变化、土地利用调控的响应,结果表明:(1)流域内第二个时段年均有效降雨最大,其次是第一个时段,第三个时段的最小;(2)流域内主要以有林地为主,旱地、建设用地持续增加但增长速率减缓,总体上流域植被覆盖度呈现上升趋势;(3)流域整体的岩溶碳汇强度由大到小依次为2002年、1990年、2016年,水田与旱地对岩溶碳汇贡献较大;(4)气候变化与土地利用共同控制岩溶碳汇,碳汇强度可能不随地类正向演替而增大。 相似文献
18.
祁连山海北高寒湿地植物群落结构及生态特征 总被引:10,自引:3,他引:7
海北高寒湿地系沼泽型和湖泊型湿地相并存.海北高寒湿地植物种类组成较少,从湿地中央到边缘植物优势种组成不同,群落结构变化明显.中部以帕米尔苔草为主要植物建群种的沼泽草甸,边缘地带以藏嵩草为主要建群种的沼泽化草甸,从中央到边缘地带主要有25种植物组成,隶属10科20属.高寒湿地植物有较高的地上生物量(349.373 g·m-2)和地下生物量(仅1~40 cm层次最高可达10769.301 g·m-2),而且地下部分远高于地上部分,地下生物量从表层到深层基本均匀下降,与矮嵩草草甸和金露梅灌丛草甸区的地下生物量分布截然不同.因湿地帕米尔苔草、藏嵩草、黑褐苔草、华扁穗草等为主的植物粗纤维高,牲畜利用率下降,不论地上还是地下对土壤有机物的补给均较高,多年的积累使其海北高寒湿地有深达2~3 m的泥炭层,使湿地形成一个非常重要的碳库.在气候变暖的条件下,这些未分解或半分解的土壤有机物质(或残体)将加速分解,对大气有更多的CO2、CH4等温室气体的排放. 相似文献
19.
Growing wetland loss along a coastal area in China was examined through shoreline recession and land use changes. Carbon storage or sequestration in coastal wetland soils was based on vertical marsh accretion and aerial change data. Marshes sequester significant amounts of carbon through vertical accretion; however, large amounts of carbon previously sequestered in the soil profile are lost through rapid land use changes and shoreline recessions. The Liaohe Delta (LHD) was divided into nine landscape types based on Landsat TM digital images from 1991 to 2011. The distributed areas and transfer matrices of each landscape type were calculated. Combined with the organic carbon content and bulk density of 202 soil surface samples from field investigations in 2012, the soil organic carbon pools and stocks were estimated. Results showed that the soil organic carbon pools varied from 0.58 to 9.75 kg m?2, and organic carbon storage in the upper 20 cm of soil was 1935.92 × 104 and 1863.87 × 104 t in 1991 and 2011, respectively. We attributed these large losses of carbon to rapid land use changes. The construction of levees along the shoreline has triggered large instantaneous losses of previously sequestered carbon through the destruction of 278.06 km2 of tidal flats. Our results reveal that the LHD wetlands might not serve as a desired sink of carbon if maladministration practices are applied. These results can provide scientific guidance for decision makers in determining an effective way to maintain the soil carbon pool in the wetlands of the LHD. 相似文献
20.
气候变化对巴音布鲁克高寒湿地地表水的影响 总被引:7,自引:0,他引:7
通过对巴音布鲁克高寒湿地各特征气候要素的变化分析,研究了近50a来巴音布鲁克高寒湿地地表水环境和气候变化的变化趋势和年际分布特征.结果表明:巴音布鲁克湿地不论冬季还是年平均气温都没有明显的升高趋势,极端最高、最低气温也没有明显变化,但夏季增温幅度高于新疆平均水平;夏季降水量占了全年降水量的68.4%,是巴音布鲁克湿地水体的主要来源.20世纪80年代中期是降水量最少的时期,此后开始逐步增加;开都河的径流量自1987年后呈现逐步增加趋势,并与巴音布鲁克年降水量和年均气温存在良好的响应关系.气候变化对湿地水环境的影响直接关系到湿地的生态系统. 相似文献