植被覆盖度和综合治理对纸坊沟流域土壤氮素流失的影响

同小流域土壤侵蚀一样,小流域土壤氮素随洪流流失也受到植被覆盖度的影响,通常经过调整小流域内土地利用结构以达到控制水土流失.该研究以8.27 km2纸坊沟流域和1:400比例流域模型为研究对象,研究植被覆盖度和综合治理对纸坊沟流域土壤氮素流失的影响.结果表明:在模拟降雨下,当流域植被覆盖度分别为60%、40%、20%和0时,流域模型铵态氮流失量分别为87.08、44.31、25.16和13.71 kg/km2,硝态氮为85.50、74.05、63.95和56.23 kg/km2,全氮为0.81、1.18、1.98和7.51 t/km2;在自然降雨下,1998年与1992年相比,全流域年土壤侵蚀量为1 086 t/km2和1 119 t/km2,氮素流失量为8 758.5和7 562.2 kg,减少了15.8%,其中农地减少了52.0%.流域对降水中的矿质氮具有过滤作用,硝态氮的过滤作用明显高于铵态氮.洪流泥沙中＜20 μm微团聚体富集造成了泥沙有机质和全氮的富集.植被覆盖虽能有效地减少流域土壤侵蚀和全氮的流失,却能增加土壤矿质氮的流失.坡地退耕还林草可显著减少流域土壤氮素流失.     

植被覆盖度和综合治理对纸坊沟流域土壤氮素流失的影响

同小流域土壤侵蚀一样,小流域土壤氮素随洪流流失也受到植被覆盖度的影响,通常经过调整小流域内土地利用结构以达到控制水土流失。该研究以8.27 km2纸坊沟流域和1:400比例流域模型为研究对象,研究植被覆盖度和综合治理对纸坊沟流域土壤氮素流失的影响。结果表明:在模拟降雨下,当流域植被覆盖度分别为60%、40%、20%和0时,流域模型铵态氮流失量分别为87.08、44.31、25.16和13.71 kg/km2,硝态氮为85.50、74.05、63.95和56.23 kg/km2,全氮为0.81、1.18、1.98和7.51 t/km2;在自然降雨下,1998年与1992年相比,全流域年土壤侵蚀量为1 086 t/km2和1 119 t/km2,氮素流失量为8 758.5和7 562.2 kg,减少了15.8%,其中农地减少了52.0%。流域对降水中的矿质氮具有过滤作用,硝态氮的过滤作用明显高于铵态氮。洪流泥沙中<20 mm微团聚体富集造成了泥沙有机质和全氮的富集。植被覆盖虽能有效地减少流域土壤侵蚀和全氮的流失,却能增加土壤矿质氮的流失。坡地退耕还林草可显著减少流域土壤氮素流失。     

Control of plant growth by nitrogen and phosphorus in mesotrophic fens

A fertilization experiment was carried out in 3 mesotrophic fens to investigate whether plant growth in these systems is controlled by the availability of N, P or K. The fens are located in an area with high N inputs from precipitation. They are annually mown in the summer to prevent succession to woodland. Above-ground plant biomass increased significantly upon N fertilization in the two mid-succession fens studied. In the late-succession fen that had been mown for at least 60 years, however, plant biomass increased significantly upon P fertilization. The mowing regime depletes the P pool in the soil, while it keeps N inputs and outputs in balance. A long-term shift occurs from limitation of plant production by N toward limitation by P. Hence, mowing is a suitable management tool to conserve the mesothrophic character of the fens.     

基于径流路径的分布式面源污染模型研发与应用进展

精准刻画地表径流的路径及其所携带的面源污染物随径流的输移过程是准确估算面源污染入水体量、污染关键源区辨识和高效防控的关键,在我国以小农户种植为主、景观特征复杂的地理条件下尤为重要。鉴于目前常用的面源污染模型大都起源于国外,往往对径流路径的空间差异性及污染物陆面输移过程进行概化,介绍了一个基于径流路径的分布式面源污染模型(STEM-NPS)及其研发与应用进展。阐述了该模型的研发背景、模型原理和结构,说明了STEM-NPS模型对地表径流汇流及其所携带的污染物输移过程的精细化表达方法;介绍了该模型在不同地理环境及尺度的应用进展,展示了其在地块尺度的面源污染关键源区辨识,关键过程和关键影响因素解析及面源污染监管决策支持等方面的功能;探讨了STEM-NPS模型与其他常用模型的异同,并结合生态学研究和面源污染精准防控的需求,提出模型的应用前景及进一步发展的方向。     

中国主要湿地植被氮和磷生态化学计量学特征

研究湿地植物氮(N)和磷(P)的生态化学计量学特征对揭示植物与生境的耦合关系具有重要意义。通过收集中国52个采样区湿地植物不同器官和全株样本的N和P含量, 对其进行分类和统计分析, 探讨植物器官、生长期、植物类型、湿地类型和气候带对湿地植物N和P生态化学计量学特征的影响。结果表明: 1)湿地植物各器官N、P和N:P的几何平均值均表现为叶片(N, 16.07 mg·g^-1; P, 1.85 mg·g^-1; N:P, 8.67) >地上部分(N, 13.54 mg·g^-1; P, 1.72 mg·g^-1; N:P, 7.96) >茎(N, 7.86 mg·g^-1; P, 1.71 mg·g^-1; N:P, 4.58); 2)叶片N含量随时间变化呈现“三峰”型变化, 峰值分别出现在5月、7月和9月; 茎的N含量随时间变化表现为“双峰”型, 峰值出现在5月和9月; 成熟期之前, 植物叶片的N:P与N趋同波动, N:P主要受N含量控制; 衰老期N:P受P含量控制。3)湿地类型是影响植物叶片N和P生态化学计量特征的关键因素, N和P含量最高值出现在河流, 最低值出现在沼泽湿地, N:P的变化趋势大致与之相反。4)植物叶片N、P和N:P的几何平均值都表现为热带>温带>亚热带, 但总体差异不显著(p > 0.05)。5)中国大部分湿地植物叶片N:P < 14, 表现为N限制。     

面源污染最佳管理措施多目标协同优化配置研究进展

随着点源污染逐渐得到有效控制,面源污染逐渐成为我国多数地区影响水环境质量安全的主要因素。推广实施最佳管理措施(Best Management Practices, BMPs)被认为是控制面源污染的有效途径。受到区域种植制度、耕作方式、政策以及经济成本等因素的影响,导致流域尺度配置BMPs存在一定的困难,特别是随着流域空间尺度的变化,会进一步加大BMPs配置难度,使得BMPs的配置工作变为了一项多目标决策优化问题,即如何在有限的成本投入下,实现水环境质量改善的目标。需要在不同空间尺度下对流域BMPs进行多目标协同优化配置。从面源污染关键源区识别、BMPs削减效率评估以及BMPs多目标协同优化模拟3个方面对面源污染BMPs多目标协同优化配置研究进行了综述。结果表明:1)包含地块尺度和流域尺度的多尺度模型耦合系统的构建,将是实现关键源区精准识别的有效途径;2)BMPs削减效率对水质改善响应的滞后性、不确定性、时空异质性、污染物形态转换风险等均是今后BMPs削减效率评估中需要重点解决的关键问题;3)建立流域污染物负荷削减量与水质改善之间的非线性响应关系,并以此为基础将BMPs组合数据库、成本数据库以及基于进化算法的的优化配置方案进行耦合,进而构建多目标决策支持系统,以获取BMPs空间优化配置方案以及多目标成本-效益最优曲线。     

植物散流-过滤带对不同密度地表股流氮磷的消除

植物散流-过滤带是在过滤带前设置草本散流带,可细化分散地表成股水流,发挥散流带的增效作用(增强过滤带对污染物的净化).草本散流带在较稀疏地表股流下具有明显的增效作用,但对其在密集地表股流下是否存在增效作用尚不清楚.本研究通过在黄荆过滤带前设置五节芒散流带,观测过滤带在低(1条股流槽)、中(3条股流槽)、高(5条股流槽)3种地表股流密度下对氮磷的消除,探讨散流带在不同密度条件下对过滤带的增效作用.结果表明: 无论何种密度条件,五节芒-黄荆过滤带对总氮、铵氮、硝氮、总磷的消除均显著高于纯黄荆过滤带;不同密度间的五节芒-黄荆对总氮、铵氮、硝氮、总磷的去除不存在显著性差异;五节芒散流带对黄荆过滤带的增效作用不受地表股流密度的影响.     

Analysis of Recent Nutrient Emission Pathways,Resulting Surface Water Quality and Ecological Impacts under Extreme Continental Climate: The Kharaa River Basin (Mongolia)

This paper presents primary research results on nutrient emissions, resulting water quality and ecological impacts of the Kharaa river basin (Mongolia) during a three‐year water resource management study. Based on surveillance data from Mongolian environmental authorities and a complementary own monitoring scheme we calculated nutrient emissions on a sub‐basin scale. Additionally, the ecological situation of fish fauna, macroinvertebrates and their habitats were investigated on selected river sections in order to link anthropogenic pressures, nutrient status and ecological impact. Although the headwaters of the Kharaa represent natural background conditions (total nitrogen (TN) 0.46 to 0.58 mg N L^–1, total phosphorus (TP) 0.011 to 0.018 mg P L^–1) and population densities within the catchment are very low (< 10 inhabitants km^–2), the river basin is facing relatively high anthropogenic pressures on water quality in the middle and especially in the lower reaches (total nitrogen 1.50 to 1.52 mg N L^–1, total phosphorus 0.18 to 0.26 mg P L^–1). Nitrogen emissions into the Kharaa river basin were about 301 t N yr^–1 for the time period 2006–2008. For phosphorus a total emission of 56 t P yr^–1 was estimated. Main contributors are urban settlements with a high proportion of households without connection to wastewater treatment plants and, to a lesser extent, agricultural land‐use. These nutrient levels have a significant eutrophication potential in the Kharaa River and we observed functional shifts of the macroinvertebrates and fish fauna, while the drinking water abstraction through bank filtration showed no significant alteration of raw water quality. (© 2011 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

河岸带生态系统植被与土壤对水文变化的响应研究进展

河岸带的植被与土壤是生态系统重要组成部分,对于维持河岸带的生态健康、生态系统服务与可持续性具有至关重要的作用。水文变化是河岸带生态系统的首要干扰因子,系统总结了水文变化对河岸带植被的特征以及植被形态、群落分布、繁殖、生存策略的影响,并阐述了河岸带水文和植被对土壤氮磷迁移转化的影响机制。根系作为土壤与植物地上部分之间物质、能量流动与信号传导的关键纽带,目前对根系的研究还较欠缺,需要加强水文变化对河岸带湿地植物根系形态、结构、功能特征的影响机理研究,以及湿地植物对水文变化的适应机制和耐受阈值方面的探究。在微观方面,应加强水文变化与植被等多因素耦合对土壤氮磷迁移转化过程的机理研究。河流形态和土壤的多样性决定着河岸带水文作用特征的复杂性,今后需注重河岸带个性特征与水文响应的关系研究。河岸带是横向的水陆生态过渡带和河流上下游的纵向生态廊道,亟需综合考虑和模拟流域土壤、植被与水文、人类活动之间的耦合关系,预测未来气候与社会经济情境下的河岸带生态系统演变规律,为河岸带生态系统的生态调节、生物多样性保护与生态恢复等提供理论依据与技术支撑。     

黄土丘陵区植被类型对土壤微生物量碳氮磷的影响

选择黄土丘陵区延河流域4种典型植被类型下的土壤为研究对象,测定了土壤微生物量碳、氮、磷和相关基本理化性质。结果表明,在此流域的典型天然草地、人工灌木林、人工乔木林和农地中土壤微生物量碳(MBC)的含量范围分别为315.15-400.89、246.56-321.25、267.76-347.05和118.96-245.14 mg/kg,土壤微生物量氮(MBN)的含量范围分别为35.87-47.63、27.63-42.89、24.66-36.20和15.64-22.56 mg/kg,土壤微生物量磷(MBP)的含量范围分别为14.14-22.96、12.89-19.75、11.54-14.40和7.23-11.59 mg/kg;土壤微生物量总体呈现出天然草地最高、人工乔、灌木林次之,且均显著高于农地的趋势,表明退耕还林还草对土壤微生物生物量有明显的促进作用。不同植被类型下,土壤微生物量碳氮比和碳磷比的变化范围分别为7.49-10.87和16.27-24.11,土壤微生物量碳、氮、磷占土壤有机碳(SOC)、全氮(TN)、全磷(TP)百分比的范围分别为2.70%-4.85%、2.56%-4.45%、2.08%-5.34%。其中天然草地、人工灌木林和农地土壤的微生物量碳氮比、碳磷比均显著小于人工乔木林(P < 0.05); MBC/SOC在不同植被类型下的差异不显著,MBN/TN和MBP/TP均呈现出天然草地>人工灌木林>人工乔木林和农地的趋势,且差异显著(P < 0.05)。微生物量碳、氮、磷与土壤有机碳、全氮和土壤含水率呈现极显著或显著相关性,与土壤pH值呈现出不同程度的负相关性,表明植被类型对这些与土壤微生物量紧密相关的理化性质也有显著影响。     

Modelling of Nutrient Emissions in River Systems – MONERIS – Methods and Background

MONERIS is a semi‐empirical, conceptual model, which has gained international acceptance as a robust meso‐ to macro scale model for nutrient emissions. MONERIS is used to calculate nitrogen (N) and phosphorus (P) emissions into surface waters, in‐stream retention, and resulting loads, on a river catchment scale. This paper provides the first (i) comprehensive overview of the model structure (both the original elements and the new additions), (ii) depiction of the algorithms used for all pathways, and for retention in surface waters, and (iii) illustration of the monthly disaggregation of emissions and the implementation of measures. The model can be used for different climatic conditions, long term historical studies, and for future development scenarios. The minimum validated spatial resolution is 50 km², with a temporal resolution of yearly or monthly time steps. The model considers seven emission pathways (atmospheric deposition on surface waters, overland flow, erosion, tile drainage, groundwater, emissions from sealed urban areas, and point sources), and six emission sources (natural background, fertilizer application, nitrogen atmospheric deposition on arable land and other areas, urban sources, and point sources); and these are calculated separately for different land‐uses. The pathway and source‐related approach is a prerequisite for the implementation of measures to reduce non‐point and point‐source emissions. Therefore, we have modified MONERIS by the addition of a “management alternative” tool which can identify the potential effectiveness of nutrient reduction measures. MONERIS is an appropriate tool for addressing the scientific and political aspects of river basin management in support of a good surface water quality. (© 2011 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

中亚热带植被恢复阶段植物叶片、凋落物、土壤碳氮磷化学计量特征

为揭示植被恢复过程中生态系统的养分循环机制及植物的生存策略, 根据亚热带森林群落演替过程, 采用空间代替时间方法, 以湘中丘陵区地域相邻、环境条件基本一致的檵木(Loropetalum chinensis) +南烛(Vaccinium bracteatu) +杜鹃(Rhododendron mariesii)灌草丛(LVR)、檵木+杉木(Cunninghamia lanceolata) +白栎(Quercus fabri)灌木林(LCQ)、马尾松(Pinus massoniana) +柯(Lithocarpus glaber) +檵木针阔混交林(PLL)、柯+红淡比(Cleyera japonica) +青冈(Cyclobalanopsis Glauca)常绿阔叶林(LCC)作为一个恢复系列, 设置固定样地, 采集植物叶片、未分解层凋落物和0-30 cm土壤样品, 测定有机碳(C)、全氮(N)、全磷(P)含量及其化学计量比, 运用异速生长关系、养分利用效率和再吸收效率分析植物对环境变化的响应和养分利用策略。结果表明: (1)随着植被恢复, 叶片C:N、C:P、N:P显著下降, 而叶片C、N、P含量和土壤C、N含量、C:P、N:P显著增加, 其中LCC植物叶片C、N含量, 土壤C、N含量及其N:P, PLL植物叶片P含量, 土壤C:P显著高于其他3个恢复阶段, 各恢复阶段植物叶片N:P > 20, 植物生长受P限制; 凋落物C、N、P含量及其化学计量比波动较大。(2)凋落物与叶片、土壤的化学计量特征之间的相关关系较弱, 叶片与土壤的化学计量特征之间具有显著相关关系, 其中叶片C、N、P含量与土壤C、N含量、C:N (除叶片C、N含量外)、C:P、N:P呈显著正相关关系; 叶片C:N与土壤C、N含量、C:P、N:P, 叶片C:P与土壤C含量、C:N、C:P, 叶片N:P与土壤C:N呈显著负相关关系。(3)植被恢复过程中, 叶片N、P之间具有显著异速生长关系, 异速生长指数为1.45, 叶片N、P的利用效率下降, 对N、P的再吸收效率增加, LCC叶片N利用效率最低, PLL叶片P利用效率最低而N、P再吸收效率最高。(4)叶片N含量内稳态弱, 而P含量具有较高的内稳态, 在土壤低P限制下植物能保持P平衡。植被恢复显著影响叶片、凋落物、土壤C、N、P含量及其化学计量比, 叶片与土壤之间C、N、P含量及化学计量比呈显著相关关系, 植物通过降低养分利用效率和提高养分再吸收效率适应土壤养分的变化, 叶片-凋落物-土壤系统的N、P循环随着植被恢复逐渐达到“化学计量平衡”。     

农业面源氮污染控制措施滞后效应形成机理与评估方法研究进展

推广实施最佳管理措施(BMPs)被认为是防治农业面源污染的有效途径,然而许多流域实施BMPs后通常难以在预测的时间内实现水质改善目标,导致人们对BMPs的有效性提出质疑。受流域内养分遗留效应影响,BMPs实施后的环境质量改善效益可能不会立刻显现(也即“滞后期”),这是由于过去人为活动输入的过量营养物质在流域水文传输和生物地球化学转化过程中的积累所致,当来自外部的污染负荷减少时,这部分营养物质的汇集和释放可能掩盖治理措施对于水质改善的影响。鉴于遗留的营养物质在延迟水质改善方面的关键作用,滞后期的量化评估对于全面分析污染成因,科学配置BMPs,有效治理流域农业面源污染,提升水质改善效率非常重要。以农业面源氮控制措施的滞后效应形成机理和评估方法为主线,概述了流域尺度氮累积和滞后效应产生的主要机理,述评了氮污染滞后效应的量化评估方法,提出目前大多数流域模型尚不能很好的表述滞后效应以及缺乏解决水文和生物地球化学遗留效应的能力,并对未来BMPs优化配置研究提出建议：(1)摸清流域水文传输过程和生物地球化学转化过程对BMPs控氮效益滞后期的影响,分析污染负荷削减的时空响应规律;(2)构建包含土壤、浅...     

内蒙古典型草原不同退化阶段植被恢复的养分限制因子解析

草地生态系统具有固碳增汇、防风固沙和维持生物多样性等多种生态服务功能。当前部分地区草地退化问题日益严重, 亟需深入解析退化草地植被恢复的限制因子, 为天然草地植被恢复实践工作提供科学理论支撑。该研究基于内蒙古典型草原的13个采样点(每个点包含4种不同退化程度的植物群落: 未退化、轻度退化、中度退化和重度退化)调查, 探究了植物群落属性(地上生物量、盖度和密度)随草地退化程度的变化规律, 并利用最小二乘回归分析、冗余分析和多元线性回归分析等多种统计分析方法解析了退化草地植被恢复的养分限制因子。结果显示: 1)随着退化程度的加剧, 内蒙古典型草原植物群落地上生物量、盖度和密度以及土壤有机碳、总氮和速效磷含量显著降低。2)整体退化阶段以及相邻的退化演替阶段之间, 土壤氮含量是对植物群落属性变化最大的影响因素, 土壤磷含量仅在草原整体退化阶段具有一定影响。上述结果表明, 土壤氮的可利用性是内蒙古典型草原退化植被恢复最重要的养分限制因子, 在退化草原恢复工作中应发展以氮肥施用为主的养分管理措施。     

模拟氮沉降对杉木幼苗细根化学计量学特征的影响

为了揭示全球氮(N)沉降对杉木人工林细根碳(C)、N、磷(P)元素组成的影响,在福建三明陈大国有林场开展杉木(Cunninghamia lanceolata)幼苗模拟N沉降试验,设置了对照(CK)、低N(LN,40 kg N hm~(-2)a~(-1))、高N(HN,80 kg N hm~(-2)a~(-1))3个处理,每个处理5个重复。采用内生长环法通过2年4次取样探讨N沉降对细根C、N、P化学计量学的影响。结果显示:(1) N添加在2015年降低细根C浓度,此后低N处理无影响,高N添加在2016年增加了细根C浓度;高N添加提高了细根(特别是0—1 mm细根) N浓度,但低N添加则无显著影响,甚至在2016年7月显著降低细根N浓度; N添加在2015年对细根P浓度无显著影响,但在2016年导致细根(特别是0—1 mm细根) P浓度降低。(2)低N添加在2016年显著提高细根的C∶N比,而高N添加则在2015年1月显著降低细根的C∶N比;低N添加对细根N∶P比没有显著影响,而高N添加则在大部分取样时间里显著增加了细根N∶P比。(3)不同处理细根C浓度、C∶N比均随着时间的增加呈增加趋势,而细根N浓度和N∶P比呈降低趋势。本研究表明,N添加对杉木细根化学计量学特征的影响因不同N添加水平而异,并受苗木生长的稀释效应所调节。     

Albedo estimates for land surface models and support for a new paradigm based on foliage nitrogen concentration

Vegetation albedo is a critical component of the Earth's climate system, yet efforts to evaluate and improve albedo parameterizations in climate models have lagged relative to other aspects of model development. Here, we calculated growing season albedos for deciduous and evergreen forests, crops, and grasslands based on over 40 site‐years of data from the AmeriFlux network and compared them with estimates presently used in the land surface formulations of a variety of climate models. Generally, the albedo estimates used in land surface models agreed well with this data compilation. However, a variety of models using fixed seasonal estimates of albedo overestimated the growing season albedo of northerly evergreen trees. In contrast, climate models that rely on a common two‐stream albedo submodel provided accurate predictions of boreal needle‐leaf evergreen albedo but overestimated grassland albedos. Inverse analysis showed that parameters of the two‐stream model were highly correlated. Consistent with recent observations based on remotely sensed albedo, the AmeriFlux dataset demonstrated a tight linear relationship between canopy albedo and foliage nitrogen concentration (for forest vegetation: albedo=0.01+0.071%N, r²=0.91; forests, grassland, and maize: albedo=0.02+0.067%N, r²=0.80). However, this relationship saturated at the higher nitrogen concentrations displayed by soybean foliage. We developed similar relationships between a foliar parameter used in the two‐stream albedo model and foliage nitrogen concentration. These nitrogen‐based relationships can serve as the basis for a new approach to land surface albedo modeling that simplifies albedo estimation while providing a link to other important ecosystem processes.     

Nutrient limitations and their implications on the effects of atmospheric deposition in coastal dunes; lime‐poor and lime‐rich sites in the Netherlands

1 A survey of plant and soil parameters was carried out in dry dune grasslands along the Dutch coast in the lime‐ and iron‐poor Wadden district and initially lime‐ and iron‐rich Renodunaal district, in order to detect differences in nutrient availability related to soil characteristics and potential sensitivity to atmospheric deposition of nitrogen.
2 Plant biomass and phosphorus pools in the shoot were higher in the Wadden district. The low foliar nitrogen concentrations and nitrogen/phosphorus ratios in the Wadden district suggested nitrogen‐limitation, while in the Renodunaal district there appeared to be a balanced supply of both nitrogen and phosphorus.
3 Soil pH, soil organic matter, soil nitrogen and phosphorus concentrations and total amounts were generally higher in the Renodunaal district. In both districts mineral phosphorus decreased with acidification and phosphorus oxalate (iron and aluminium bound) increased.
4 In the Wadden district iron is present primarily in iron–organic matter complexes, which leads to reversible binding of phosphorus. In the Renodunaal district large amounts of iron (hydr)oxides occur and at high pH may contribute to reversible phosphorus‐sorption, but at low pH this probably leads to immobilization of phosphorus.
5 While pools of soil phosphorus are low in the Wadden district, the phosphorus availability may be relatively high due to the comparatively loose nature of phosphorus‐sorption. As a result the area may be nitrogen‐limited and grass‐encroachment may thus have resulted from atmospheric deposition of nitrogen.
6 In the Renodunaal district, atmospheric deposition probably only accelerates grass‐encroachment, because deposition of acid and nitrogen increases the availability of both nitrogen and phosphorus and maintains the 'co‐limitation'.     

黄土高原典型植被恢复过程土壤与叶片生态化学计量特征

为揭示黄土高原典型人工植被恢复过程中植物叶片与土壤碳(C)、氮(N)、磷(P)元素变化特征及其交互作用,以延安庙咀沟流域恢复20—40a的刺槐(Robinia pseudoacacia)、柠条(Caragana korshinskii)、草地和坡耕地(对照)为研究对象,分析了各样地植物叶片和土壤C、N、P化学计量的变化特征及相互关系。结果表明:从20a到40a的恢复过程中,3种植被叶片C含量均显著增加,草地叶片P含量显著升高,而刺槐、柠条叶片N和P含量则显著降低。刺槐、柠条及草地土壤C、N、P含量随着恢复年限的延长而增加,比耕地分别增加了70%—349%、27%—202%、13%—62%(P0.05),其中刺槐的增幅最大。从增速来看,刺槐和柠条林土壤表层C、N增速表现为前期(0—20a)大于后期(20—40a),而草地则相反。在20—40a的恢复过程中,刺槐、柠条叶片C∶N、C∶P均显著增加,草地叶片C∶P、N∶P则显著降低。恢复过程中,土壤C∶P在刺槐和草地中显著增加,而土壤N∶P仅在草地中显著增加,土壤C∶N则没有显著变化。相关性分析显示叶片C和土壤C、N、P显著正相关,叶片N、P和土壤N显著正相关,叶片和土壤N∶P显著正相关,叶片P、C∶P与土壤C、N增速显著相关,表明叶片P可以指示土壤C、N增速的变化,而N∶P可以将植物和土壤联系起来。植被恢复过程中,叶片和土壤C、N、P含量及增速均发生显著变化,且存在密切的联系,这种变化的趋势在刺槐、柠条和草地中有所不同。     

Flood Detention, Nature Development and Water Quality along the Lowland River Sava, Croatia

The construction or designation of detention areas along lowland rivers is considered along many European rivers. Since Croatia accommodates large detention areas, both natural (e.g., Mokro Polje) and controlled (Lonjsko Polje), it serves as an excellent example for planned detention areas elsewhere in Europe. This modelling study focuses on the controlled detention area of Lonjsko Polje. The flooding characteristics of the area are assessed in combination with the vegetation development and the transport and storage of sediment and phosphorus. Results of the modelling show that it is not so much the intake capacity that determines the flood duration time of a detention area, but the drainage capacity. A too long inundation duration following a flood event is shown to lead to major shifts in the vegetation composition. The results further indicate that about 30% of the sediment and adsorbed phosphorus that enters the detention area during an extreme (1:100 years) flood is retained within the area; this is about 10% of the total sediment and adsorbed phosphorus load of the Sava. Results of this study can be used to properly design and manage detention areas along lowland rivers.