Eutrophication of Two Lakes in Kinmen Island (Taiwan)

Water quality was monitored for 12 months in Lake Tai and Lake Zon on Kinmen Island, Taiwan, and physico-chemical conditions were analyzed. No vertical temperature stratification was observed in these shallow lakes. pH is neutral to alkaline and associated with vigorous algal growth. Nitrogen levels are high and present in various forms due to progressive nitrification. Green and blue-green algae play an important part in the process of nitrification.

Assessment of lake eutrophication was made by the use of the N:P ratio, the Trophic State Index (TSI) and the US EPA Eutrophic Screening Model. the result of these calculations indicates eutrophic conditions in both lakes. It is advised that lake restoration be initiated and available techniques are listed.     

The Impact of the Hyperacid Ijen Crater Lake. Part I: Concentrations of Elements in Crops and Soil

In Asembagus (East Java, Indonesia) irrigation water is contaminated with effluent from the hyperacid Ijen Crater Lake resulting in a low pH and high levels of various elements. As a first step towards a risk assessment, locally produced food items (rice, maize, cassava leaf, cassava root, peanuts) were collected and concentrations of As, B, Ca, Cd, Co, Cu, Fe, Mg, Mn, Mo, Ni, Pb, V, Zn were compared to samples from a reference area and with literature values. Further, concentrations in rice were compared to total soil concentrations in paddy fields. Compared to the reference area, food items produced in the contaminated area had increased levels of Cd, Co, Ni and Mn in particular, while levels of Mo were lower. In contrast, total soil concentrations of Cd and Mn in particular have decreased whereas especially Mo was increased. In combination with the observed soil acidification, it is likely that the bioavailable concentration of most elements in the contaminated soil is higher (except for Mo) due to an increased weathering rate and/or input via the contaminated irrigation water. In terms of human health, concentrations in foods were generally within normal literature values. However, it was observed that essential elements (in particular Fe) known for their inhibitory effects on e.g. Cd and Mn toxicity did not accumulate in crops whereas Cd and Mn did.     

川西亚高山针叶林土壤硝化作用及其影响因素

采用BarometricProcessSeparation(BaPS)技术对川西亚高山针叶林土壤总硝化作用速率的季节动态进行了研究,并分析了各影响因素与总硝化速率的关系.通过土壤温度和水分含量的控制实验,对温度和水分含量与总硝化速率之间的关系进行了一次线性和曲线模拟.结果表明,6至10月各月份之间的总硝化速率存在显著差异(P<0.01),在7月总硝化速率达到最大值;土壤温度和水分含量与总硝化速率显著正相关(P<0.05),对总硝化速率的影响存在明显的交互作用,水分含量可能对总硝化速率的影响更大,在季节变化中温度和水分含量可能对硝化过程产生直接和间接两种作用;pH值与总硝化速率之间的相关性不明显;森林凋落量与总硝化速率间没有显著相关性,但若仅考虑6至9月,森林凋落量与总硝化速率极显著相关(P<0.01).总之,土壤温度和水分含量很可能是影响总硝化速率的两个最主要的因素.图6表2参31     

川西亚高山白桦林小气候的时空动态特征

对川西亚高山白桦林(海拔2 540 m)内太阳辐射、空气温湿度以及土壤5 cm和15 cm层温度等进行了连续的定位观测.结果表明:1)林冠下的太阳辐射日进程与林冠上的不同,但辐射强度随着太阳高度角的变化而变化;林冠下太阳辐射日总量不仅受林冠上辐射日总量的影响,也受森林群落生长季节的影响;春、夏和秋季,林冠下平均辐射日总量分别占林冠上平均辐射日总量的53.1%、39.4%和55.8%.2)夏季,白天空气温度高于土壤温度,而夜间则相反;空气温度和土壤温度的日极端温度出现的时间不同步,空气温度对太阳辐射强度的敏感性比土壤温度的敏感性高.3)春季,土壤表层>4℃的积温高于空气和土壤底层>4℃的积温;夏季,>4℃的积温由高到低的次序为:林冠下空气>土壤5 cm层>土壤15 cm层,而秋季的比较结果与之相反;空气日平均温度与土壤日平均温度有显著的线性关系(P<0.001).4)林冠下的空气相对湿度(RH)比林冠上的高,林冠下的空气RH日变幅和季节性变幅比林冠上的小.图7表1参19     

围栏禁牧对川西北亚高山高寒草甸群落结构的影响

围栏禁牧4a后,与放牧草地相比较:1)围栏草地物种数量有所下降,群落内出现物种27种,而长期放牧草地为33种.2)围栏草地物种平均高度较高,为20.23cm,群落分层现象明显;放牧草地物种平均高度仅为8.14cm,群落无分层现象.3)围栏草地内,杂草类的盖度(98%)大于禾草类的盖度(14%);放牧草地上,杂草类的盖度(53%)小于禾草类的盖度(56%)。4)围栏草地以禾草为主的优良牧草的生产能力(35.24g/m2)低于放牧草地的生产能力(75.47g/m2).5)围栏草地的地上生物量(272.64g/m2)和地下0～30cm生物量(801.61g/m3)都高于放牧草地的地上生物量(184.84g/m2)和地下0～30cm生物量(683.82g/m3).研究结果表明,围栏草地具有比放牧草地更复杂的群落结构,但其物种组成和优良牧草的生产能力,都低于放牧草地.     

亚高山30a人工针叶林物种多样性的定量分析

探讨了川西地区不同海拔梯度上,30a亚高山人工针叶林乔,灌,草各层物种多样性的变化规律,并运用逐步多元回归分析方法,分析了不同立地条件下土壤因子与针叶林群落乔,灌,草各层物种多样性指数之间的关系,结果显示：30a人工针叶林灌木层和草本层多样性指数明显高于乔木层;随着海拔的升高,灌木层和草木层物种的多样性指数逐渐降低,在halt2700m处多样性最丰富,乔木物种多样性则呈现为“低→高→低”的变化趋势,符合“中间高度膨胀（mid-altitude bulge)模式,土壤因子对30a人工恢复针叶林多样性的影响主要是体现在灌木层和草本层的变化,而对乔木层物种多样性的影响不明显,土层厚度,土壤容重,石砾含量,枯枝落叶的贮量,CaO含量以及有机质的C／N比值等土壤因子与灌木层和草本层物种多样性之间存在线性相关关系,分层建立了物种数,Simpson指数,ShannonWiener指数,Menhinick指数以及Brillouin指数与相关土壤因子的回归模型。     

移动式絮凝-气浮集成系统研制及其在城市污染河湖治理中的应用

针对北京城市河湖的污染状况,论述了传统絮凝-气浮工艺在污染治理中的应用研究及以该工艺为基础的集成系统的开发.结果表明,该系统对TP、COD去除率分别达81%和75%.该系统的研制成功为城市河湖的污染治理开辟了新途径.     

Biological Connectivity of Seasonally Ponded Wetlands across Spatial and Temporal Scales

Many species that inhabit seasonally ponded wetlands also rely on surrounding upland habitats and nearby aquatic ecosystems for resources to support life stages and to maintain viable populations. Understanding biological connectivity among these habitats is critical to ensure that landscapes are protected at appropriate scales to conserve species and ecosystem function. Biological connectivity occurs across a range of spatial and temporal scales. For example, at annual time scales many organisms move between seasonal wetlands and adjacent terrestrial habitats as they undergo life‐stage transitions; at generational time scales, individuals may disperse among nearby wetlands; and at multigenerational scales, there can be gene flow across large portions of a species’ range. The scale of biological connectivity may also vary among species. Larger bodied or more vagile species can connect a matrix of seasonally ponded wetlands, streams, lakes, and surrounding terrestrial habitats on a seasonal or annual basis. Measuring biological connectivity at different spatial and temporal scales remains a challenge. Here we review environmental and biological factors that drive biological connectivity, discuss implications of biological connectivity for animal populations and ecosystem processes, and provide examples illustrating the range of spatial and temporal scales across which biological connectivity occurs in seasonal wetlands.     

富营养水体中常绿水生植被组建及净化效果研究

1992～1993年在富营养湖泊五里湖中开展了常绿型人工水生植被组建实验,在面积为2000m²的半封闭式围隔实验区中,选用耐寒植物伊乐藻和喜温植物菱及风眼莲,组建成了常绿型人工水生植被。这种常绿型人工水生植被不仅使实验区内常年保持较好的水质,而且对外来污染冲击有很强的缓冲能力。它可用于水源保护、局部性水质控制、污水净化生态工程、小型富营养水体的生态恢复等。如能解决耐寒型沉水植物伊乐藻与喜温型沉水植物种类间的衔接过渡,这种常绿型人工水生植被技术还可望用于富营养水体中天然水生植被的恢复。     

RESPONSE OF NORTH AMERICAN FRESHWATER LAKES TO SIMULATED FUTURE CLIMATES1

ABSTRACT: We apply a physically based lake model to assess the response of North American lakes to future climate conditions as portrayed by the transient trace-gas simulations conducted with the Max Planck Institute (ECHAM4) and the Canadian Climate Center (CGCM1) atmosphere-ocean general circulation models (A/OGCMs). To quantify spatial patterns of lake responses (temperature, mixing, ice cover, evaporation) we ran the lake model for theoretical lakes of specified area, depth, and transparency over a uniformly spaced (50 km) grid. The simulations were conducted for two 10-year periods that represent present climatic conditions and those around the time of CO₂ doubling. Although the climate model output produces simulated lake responses that differ in specific regional details, there is broad agreement with regard to the direction and area of change. In particular, lake temperatures are generally warmer in the future as a result of warmer climatic conditions and a substantial loss (> 100 days/yr) of winter ice cover. Simulated summer lake temperatures are higher than 30°C over the Midwest and south, suggesting the potential for future disturbance of existing aquatic ecosystems. Overall increases in lake evaporation combine with disparate changes in A/OGCM precipitation to produce future changes in net moisture (precipitation minus evaporation) that are of less fidelity than those of lake temperature.