设计配置对生物滞留设施污染物去除性能的影响研究

生物滞留是一种常用的低影响开发技术,通过不同机理去除径流中的各种污染物。设施面积、消能池设置、表面覆盖物的合理设计可降低外界的不利影响;内部斜坡与多元结构可优化设施性能,介质层的改良填料和较长深度可提高污染物的去除效率;配置适宜植物可提高环境耐受能力与污染物去除效果,引入多样植物可提高设施生物多样性,有利于发挥动植物相互作用,提高设施的稳定性与整体性能。     

Atmospheric Change and Biodiversity

Strategies to conserve biodiversity need to include the monitoring, modelling, adaptation and regulation of the composition of the atmosphere. Atmospheric issues include climate variability and extremes; climate change; stratospheric ozone depletion; acid deposition; photochemical pollution; suspended particulate matter; and hazardous air pollutants. Coarse filter and fine filter approaches have been used to understand the complexity of the interactions between the atmosphere and biodiversity. In the first approach, climate-based models, using GIS technology, helped create future biodiversity scenarios under a 2 × CO₂ atmosphere. In the second approach, the SI/MAB forest biodiversity monitoring protocols helped calibrate the climate-forest biodiversity baseline and, as global diagnostics, helped identify where the biodiversity was in equilibrium with the present climate. Forest climate monitoring, an enhancing protocol, was used in a co-location approach to define the thermal buffering capacity of forest ecosystems and their ability to reduce and ameliorate global climate variability, extremes and change.     

醌指纹法及其在环境微生物领域的应用

微生物在环境中的丰度和多样性受到广泛关注.系统介绍了一种通过分析微生物菌群中电子传递体的种类和数量来表征其群落丰度和多样性的方法——醌指纹法.综述了醌指纹法的原理和检测分析手段,归纳了醌指纹法在废水处理、水体、土壤和堆肥环境场景中的应用,此外还分析了醌指纹法的优缺点.最后,对醌指纹法在未来微生物治理领域的应用进行了展望...     

中国生物多样性信息主页的研究与开发

中国生物多样性信息主页介绍了我国生物多样性现状和生物多样性保护的政策、法规、规划、计划、履约工作动态等信息,是《生物多样性公约》资料交换所机制的重要组成部分．本文对主页进行系统分析和系统设计,并应用 Front Page 98 进行系统开发．该主页可访问我国生物多样性重要数据源点．为使主页内容具有新意,需经常更新主页．     

Succession of aquatic microbial communities as a result of the water quality variations in continuous water

The changes of structural and functional parameters of aquatic microbial communities in continuous water on campus of Tsinghua University, China are investigated by polyurethane foam unit(PFU) method. The measured compositions of the communities include alga, protozoa, and some metazoa (such as rotifers). The measured indicators of water quality include water temperature, pH value, dissolved oxygen (DO), potassium permanganate index(CODMn), total nitrogen(TN), total phosphorus(TP) and chlorophyll- a(Chla). The trophic level, expressed by the trophic level indices(TL/c), is assessed with analytic hierarchy process and principal component analysis (AHP-PCA) method. The changing trends of the structural and functional parameters of aquatic microbial communities, such as Margalef index of diversity(D), Shannon-weaver index of diversity (H), Heterotropy index (HI), number of species when the colonization gets equilibrium(Seq), colonizing speed constant(G) and time spent when 90 percent of Seq colonized in PFU ( T90% ), are also analyzed. The experimental results showed the succession of aquatic microbial communities along the water flow is consistent with the water quality changes, so the parameters of microbial community can reflect the changes of water quality from the ecological view.     

A strategy for the next decade to address data deficiency in neglected biodiversity

Measuring progress toward international biodiversity targets requires robust information on the conservation status of species, which the International Union for Conservation of Nature (IUCN) Red List of Threatened Species provides. However, data and capacity are lacking for most hyperdiverse groups, such as invertebrates, plants, and fungi, particularly in megadiverse or high-endemism regions. Conservation policies and biodiversity strategies aimed at halting biodiversity loss by 2020 need to be adapted to tackle these information shortfalls after 2020. We devised an 8-point strategy to close existing data gaps by reviving explorative field research on the distribution, abundance, and ecology of species; linking taxonomic research more closely with conservation; improving global biodiversity databases by making the submission of spatially explicit data mandatory for scientific publications; developing a global spatial database on threats to biodiversity to facilitate IUCN Red List assessments; automating preassessments by integrating distribution data and spatial threat data; building capacity in taxonomy, ecology, and biodiversity monitoring in countries with high species richness or endemism; creating species monitoring programs for lesser-known taxa; and developing sufficient funding mechanisms to reduce reliance on voluntary efforts. Implementing these strategies in the post-2020 biodiversity framework will help to overcome the lack of capacity and data regarding the conservation status of biodiversity. This will require a collaborative effort among scientists, policy makers, and conservation practitioners.     

Assessing the current state of ecological connectivity in a large marine protected area system

The establishment of marine protected areas (MPAs) is a critical step in ensuring the continued persistence of marine biodiversity. Although the area protected in MPAs is growing, the movement of individuals (or larvae) among MPAs, termed connectivity, has only recently been included as an objective of many MPAs. As such, assessing connectivity is often neglected or oversimplified in the planning process. For promoting population persistence, it is important to ensure that protected areas in a system are functionally connected through dispersal or adult movement. We devised a multi-species model of larval dispersal for the Australian marine environment to evaluate how much local scale connectivity is protected in MPAs and determine whether the extensive system of MPAs truly functions as a network. We focused on non-migratory species with simplified larval behaviors (i.e., passive larval dispersal) (e.g., no explicit vertical migration) as an illustration. Of all the MPAs analyzed (approximately 2.7 million km²), outside the Great Barrier Reef and Ningaloo Reef, <50% of MPAs (46-80% of total MPA area depending on the species considered) were functionally connected. Our results suggest that Australia's MPA system cannot be referred to as a single network, but rather a collection of numerous smaller networks delineated by natural breaks in the connectivity of reef habitat. Depending on the dispersal capacity of the taxa of interest, there may be between 25 and 47 individual ecological networks distributed across the Australian marine environment. The need to first assess the underlying natural connectivity of a study system prior to implementing new MPAs represents a key research priority for strategically enlarging MPA networks. Our findings highlight the benefits of integrating multi-species connectivity into conservation planning to identify opportunities to better incorporate connectivity into the design of MPA systems and thus to increase their capacity to support long-term, sustainable biodiversity outcomes.     

不同营养状态水体中生态浮床对浮游植物群落的影响

为研究不同营养状态下水体中浮游植物群落对生态浮床系统的响应关系及其影响因素,设不同营养水平试验组〔A组ρ(COD_Cr)、ρ(NH₄+-N)、ρ(TP)分别为10.0、2.00、0.200 mg/L,B组分别为100.0、20.00、2.000 mg/L〕,每组设对照、框式浮床2个处理,每个处理3个重复. 自2012年8月5日—10月5日,定期对水体营养盐质量浓度、浮游生物群落特征、浮床植物的生长状况进行检测. 结果显示:①2个试验组浮床植物长势良好,其中B组浮床植物茎叶部分干物质量增加7.9倍,浮床系统对水体N、P的净去除率均在60%以上;②浮床系统能明显抑制浮游植物的大量生长(P＜0.05),对浮游植物密度和总生物量在峰值处的最大抑制率可达75.9%(A组)和83.6%(B组);③框式浮床处理中浮游植物的群落结构比对照处理复杂,A组中浮游植物优势种为隐藻门的卵形隐藻(Cryptomonas ovata)、尖尾蓝隐藻(Chroomonas acuta)和绿藻门的四尾栅藻(Scenedesmus quadricauda)、小空星藻(Coelastrum microporum),B组为隐藻门的尖尾蓝隐藻和裸藻门的梭形裸藻(Euglena acus);④B组试验中,框式浮床处理浮游植物Shannon-Wiener多样性指数显著高于对照处理,生态浮床对浮游植物群落的影响更多体现在提升浮游植物的生物多样性上. 研究表明,浮床系统能高效去除水体N、P,抑制浮游植物的增殖,改变浮游植物的群落结构,并且这些作用受到水体营养水平的影响.      

常温厌氧MBR中微生物群落结构与膜污染研究

为考察微生物群落结构与膜污染的关系,在常温下运行厌氧膜生物反应器,并应用末端限制性片段长度多态性分析(T-RFLP)技术,对膜丝表面微生物群落结构变化进行了研究,同时考察了微生物群落结构变化与反应器中溶解性微生物产物(SMP)、胞外聚合物(EPS)的关系.结果表明:在常温状态下膜污染周期约为18d,CODCr的去除率约为93%,运行效果稳定;微生物代谢产物的浓度随着微生物种群的演替呈逐渐升高的趋势,加速了膜污染进程;膜压(pTM)处于缓慢上升期时,膜丝表面微生物优势菌群为Raoultella、Owenweeksia hongkongensis,膜压(pTM)处于稳定上升期时,膜丝表面的优势菌群演替为 Delftia acidovorans、Halothiobacillus neapolitanus,最后当膜压(pTM)处于快速上升期时,bp78的微生物成为了膜丝表面的顶级群落.膜压(pTM)处于缓慢上升期和稳定上升期时,膜压(pTM)与微生物群落结构的多样性呈显著正相关;膜污染进入快速上升期时,膜丝表面出现了顶级群落,此时微生物群落多样性明显降低且与膜压升高呈弱相关;膜丝表面微生物群落均匀度随着膜压(pTM)的升高呈现出先增高后降低的趋势,膜丝表面微生物群落经历了不断附着,相互竞争至顶级群落出现的演替过程.