基于Meta分析的中国湖沼湿地生态系统服务价值转移研究

Meta分析价值转移方法作为资源价值评估的一种有效方法,在国外已经有大量的实证研究出现,但是在国内相应的实证研究非常稀少,有关该方法在湖沼湿地生态系统服务价值评估的应用研究还尚未见报道。通过收集有关中国湖沼湿地生态系统服务价值评估的实证研究文献的价值评估结果,建立价值转移数据库,应用Meta分析和多元回归分析方法构建中国湖沼湿地生态系统服务的Meta分析价值转移模型,并对该模型用于样本外价值转移的有效性做出评估,探讨Meta分析价值转移方法在中国湖沼湿地生态系统服务价值评估领域的可应用性及发展前景。研究结果表明:(1)在样本文献中,通常洪水调蓄和水源涵养服务是湖沼湿地提供的经济价值最高的生态系统服务,而水质净化服务的经济价值最低;(2)湖沼湿地面积、生态系统服务受益人口数量、不同生态系统服务之间的价值差异以及不同价值评估方法的使用会影响湖沼湿地生态系统服务价值的变化;(3)Meta分析价值转移模型用于样本外价值转移的有效性检验结果显示,样本外价值转移的转移误差范围在0.09%—234.61%之间,平均转移误差为19.99%,在自然资源价值转移的可接受误差范围内,因此Meta分析价值转移方法是评估湿地生态系统服务价值的一种可行且快速的方法。     

间套作种植提升农田生态系统服务功能

间套作是指在同一块土地上同时种植两种或两种以上的作物,能够充分利用有限资源,提升单位面积物质产出,同时还具有多重其他生态效益,是一种基于生物多样性的可持续农业发展范式.生态系统服务是评价生态系统功能的重要突破口,也是当前生态学领域研究的热点问题.从生态系统服务的角度论述间套作种植提升农田生态系统服务功能,并从物质产出、土壤肥力维持、生物多样性保护、水土保持、病虫草害和有害污染物控制等方面论述了间套作种植提升农田生态系统功能的实践及机制.在此基础上,构建了间套作农田生态系统服务功能评价的理论框架和指标体系,并提出了间套作种植农田生态系统未来应加强的研究方向.     

Use of a municipal environmental quality index for understanding and management of aquatic habitats and fish populations

This study describes the use of a technique developed to assess environmental quality in a municipality. The Environmental Quality Index (EQI) is a tool that can aid land-use planning, permitting a maximum understanding of the implications for the ecology of an area. A matrix shows the status of each of a series of environmental parameters at each time that an EQI is formulated. Time series analysis is used to quantify environmental impacts on a discrete community's ecosystem: this process allows the graphing of the dynamics of a changing natural resource. Thus, correlation of abiotic changes can be made with changes in biota: for instance, a correlation between proximity to effluents from sewage treatment plants and fish and aquatic plant species diversity is useful information in the managcrnent of fishery resources. Similarly, knowledge of the rate of shift from lotic to lentic waters, due to increased impounding, and its relationship to aquatic plant species diversity is important for land-use planners who are sensitive to environmental considerations. Decisions made with environmental preservation in mind will help to maintain high quality aquatic habitats.     

水源涵养与水文调节:和而不同的陆地生态系统水文服务

水与生态系统的关系是重要的科学问题,并且受到社会广泛关注。水源涵养和水文调节都是陆地生态系统所能提供的水文服务,并从生态水文和水资源角度把生态系统的健康和完整性与人类社会的持续发展紧密联系起来,从而也要求动态和综合的视角加以深入研究。基于生态水文过程原理,对水源涵养和水文调节的概念进行了辨析,认为前者是后者的有机组成部分,相对具体、应用中务求精确明晰;后者则更具包容性、客观性和广泛适用性。文章进一步简要分析了当前国内外生态系统水源涵养和水文调节服务的主导评估方法,结果表明,水源涵养的评估以储水量法为主,而水文调节则以基于降水和蒸散的水量平衡法及综合模型法(如SWAT)为主。从生态系统服务相互作用的角度考量,实际上水源涵养和水文调节及其相关的其它服务类型(如固碳、土壤保持、生物生产、淡水供给等)存在着复杂的动态权衡或协同关系,在科学研究和生态系统管理实践中必须统筹考虑,以确保对科学问题的准确把握和促进"水-生态-社会系统"的高效、可持续发展。为此,必须加强对生态水文过程的长期观测和实验研究,并且关注空间异质性及尺度效应、时间动态性和利益相关者需求的多维性。     

广东古兜山自然保护区森林生态系统服务价值评估

森林生态系统对维持自然生态系统格局、功能和过程具有特殊的生态意义。该文以广东省古兜山自然保护区为例,探讨了自然保护区森林生态系统服务功能的价值。采用市场价值法、影子工程法、替代花费法等对古兜山自然保护区森林生态系统服务功能价值进行评估,得出古兜山自然保护区每年森林生态系统服务功能总价值为57887615元。其中生产功能价值为6937700元,每年森林景观与游憩的平均价值为4050000元,森林生态系统改善大气环境的年总价值约32212700元,涵养水源与净化水质的年总价值为5809000元,森林保育土壤的年总价值为8878215元。该研究的目的在于以数值来显示自然保护区森林生态系统所提供的生态服务功能价值是巨大的,从而加深全社会对生态服务价值的认识,加强对森林生态系统服务功能的管理与保护。     

Development of a Consumer Environmental Index and Results for Washington State Consumers

Consumer choices affect sustainability of societal systems, and state governments increasingly are interested in environmental impacts of consumption. This article describes a Consumer Environmental Index (CEI) to track the impacts of product purchase, use, and disposal and applies this initial CEI to Washington State in the United States. CEI has modules for product and service use, upstream resource extraction and manufacturing, and downstream disposal. CEI uses hybrid life cycle assessment (LCA) methods, combined with purchasing data from the Bureau of Labor Statistics (BLS) Consumer Expenditure Survey. For Washington State, when human health and ecosystem toxicity impact was assessed with the TRACI/CalTOX methods, weighted aggregate and per consumer impacts in all categories increased during the 6 years from 2000 to 2005. For impacts per real dollar spent, only the CEI's climate change component declined, falling nearly 7% between 2000 and 2005. Purchasing details in the BLS expenditure surveys enable the CEI to track environmental impact details on 700 individual categories of products and services. For example, sugar, motor oil, and wood heat appear to have serious environmental impacts, whereas recycling of paper, cardboard, and food and beverage container discards can be as effective at reducing greenhouse gas emissions as cutting vehicle fuel usage nearly in half. Such results may serve to increase understanding of environmentally effective actions to reduce climate, human health, and ecosystem impacts of consumption.     

生态系统服务与自然资本价值评估

生态系统服务是生态系统提供的商品和服务,是人类生态和发展的物质基础和基本条件,是人类拥有的关键自然资本。概述了生态系统服务的内涵及类型,介绍了当前国内外有关生态系统服务及自然资本的价值理论、价值评估的各种方法及其类型;评述了研究的主要进展,存在的主要问题、难点和研究的主要趋向。认为生态系统服务及自然资本的价值评估研究是建立生态－环境－经济综合核算体系（可持续发展核算体系）的重要内容和关键环节,完善价值评估的理论与经济技术方法是生态系统服务价值评估研究亟待解决的问题。     

基于陆地-水生态系统耦合的海河流域水生态功能分区

水生态功能分区是针对水生态系统特征的陆地生态系统划分,是为流域水生态管理提供生态背景和基本单元。陆地-水生态系统的耦合是水生态功能分区的核心,但多停留在个别小流域进行理论探讨,大型流域的实际案例较少。针对海河流域独特的气候、地貌、水文和人类活动特征,提出了水生态功能分区的三级指标体系。一级二级区针对气候、地貌、水文背景进行"自上而下"的分区,三级区针对人类活动对水资源、水环境、生境影响,采用"自下而上"的分区方法。最终,海河流域划分了6个一级区、16个二级区和73个三级区。研究充分体现了"以水定陆、以陆控水"的基本原则,以及"自下而上"和"自上而下"分区方法的优点,结果可为海河流域水生态管理提供科学依据,为水资源空间调配与合理利用、产业结构布局与区域协调等服务。     

生态系统服务价值测度模式与方法

为了更好地权衡人类福祉与经济发展之间、生态系统各类服务之间的关系,加速生态系统服务价值评估成为全世界生态保护与可持续发展政策制定面临的首要难题。总结了原始价值评估和价值转移两类主要的生态系统服务评估测度模式,侧重概述了价值转移的涵义、类型、历史研究、应用限制及现有的可用于价值转移的有代表性的数据库,在此基础之上归纳两类测度模式的优势和普遍存在的局限性。总体而言,基于生态功能的原始评估更适用于地区尺度的精细化管理,评估准确但相对难度大、耗时长、成本高;基于相似生境的价值转移方法更适用于国家或区域尺度进行估判和分级,估值快速但相对信息少、不确定性大、影响因素多。其后还介绍了集成了一类或多类测度模式中不同方法的综合评估模型与工具。通过分析当前主流的评估方法与日益增长的评估需求之间的矛盾,结合生态系统服务级联,最终提出基于关键生态系统特征建立简化预测模型的评估思路,目的是为了简化传统评估过程、缩短评估周期,完善并发展以往的价值转移,推动生态系统服务多尺度、大范围的摸底清查。     

Trade‐offs between land and water requirements for large‐scale bioenergy production

Bioenergy is expected to play an important role in the future energy mix as it can substitute fossil fuels and contribute to climate change mitigation. However, large‐scale bioenergy cultivation may put substantial pressure on land and water resources. While irrigated bioenergy production can reduce the pressure on land due to higher yields, associated irrigation water requirements may lead to degradation of freshwater ecosystems and to conflicts with other potential users. In this article, we investigate the trade‐offs between land and water requirements of large‐scale bioenergy production. To this end, we adopt an exogenous demand trajectory for bioenergy from dedicated energy crops, targeted at limiting greenhouse gas emissions in the energy sector to 1100 Gt carbon dioxide equivalent until 2095. We then use the spatially explicit global land‐ and water‐use allocation model MAgPIE to project the implications of this bioenergy target for global land and water resources. We find that producing 300 EJ yr^?1 of bioenergy in 2095 from dedicated bioenergy crops is likely to double agricultural water withdrawals if no explicit water protection policies are implemented. Since current human water withdrawals are dominated by agriculture and already lead to ecosystem degradation and biodiversity loss, such a doubling will pose a severe threat to freshwater ecosystems. If irrigated bioenergy production is prohibited to prevent negative impacts of bioenergy cultivation on water resources, bioenergy land requirements for meeting a 300 EJ yr^?1 bioenergy target increase substantially (+ 41%) – mainly at the expense of pasture areas and tropical forests. Thus, avoiding negative environmental impacts of large‐scale bioenergy production will require policies that balance associated water and land requirements.     

The impacts of drought on freshwater ecosystems: an Australian perspective

Southeastern Australia is presently experiencing one of the worst droughts observed in the region in the last 200 years. The consequences of drought have been far reaching both for human consumptive uses and for aquatic ecosystems, and serve to highlight several important aspects of the nature of droughts, their ecological impacts, and how humans respond to them. Running water ecosystems are the dominant form of freshwater ecosystem in Australia, yet, despite the high frequency of drought we lack a basic understanding of the consequences of long-term droughts (as distinct from seasonal droughts) as an ecosystem disturbance, and more is known about drought effects on flowing than on standing waters. Drought is well defined and characterised meteorologically, but hydrologically its characterisation is equivocal. While drought severely impacts natural aquatic ecosystems, its effects have been and are exacerbated by direct and indirect anthropogenic modifications to streams and their catchments. In streams the major impacts are the loss of water and habitat availability, and the reduction, if not severing, of connectivity (lateral, longitudinal and vertical). Despite the relative frequency of drought in Australia we have failed to develop long-term management strategies capable of contending with droughts and their impacts, particularly in catchments where human disturbances have reduced the natural resistance and resilience of aquatic ecosystems, and where the demand for consumptive water use is high and rising. Here, we provide a commentary on drought and its implications for the management of freshwater ecosystems. We begin with a general discussion of drought and its impacts on streams and rivers before discussing some of the more specific management issues and response strategies that have arisen in response to the current drought in Australia. Throughout we consider global as well as local examples. We conclude by highlighting important knowledge gaps and by providing some general principles for better incorporating droughts and their impacts into river management strategies. Handling editor: K. Martens     

Linking Water Quality and Quantity in Environmental Flow Assessment in Deteriorated Ecosystems: A Food Web View

Most rivers worldwide are highly regulated by anthropogenic activities through flow regulation and water pollution. Environmental flow regulation is used to reduce the effects of anthropogenic activities on aquatic ecosystems. Formulating flow alteration–ecological response relationships is a key factor in environmental flow assessment. Traditional environmental flow models are characterized by natural relationships between flow regimes and ecosystem factors. However, food webs are often altered from natural states, which disturb environmental flow assessment in such ecosystems. In ecosystems deteriorated by heavy anthropogenic activities, the effects of environmental flow regulation on species are difficult to assess with current modeling approaches. Environmental flow management compels the development of tools that link flow regimes and food webs in an ecosystem. Food web approaches are more suitable for the task because they are more adaptive for disordered multiple species in a food web deteriorated by anthropogenic activities. This paper presents a global method of environmental flow assessment in deteriorated aquatic ecosystems. Linkages between flow regimes and food web dynamics are modeled by incorporating multiple species into an ecosystem to explore ecosystem-based environmental flow management. The approach allows scientists and water resources managers to analyze environmental flows in deteriorated ecosystems in an ecosystem-based way.     

Estimating species richness using environmental DNA

The foundation for any ecological study and for the effective management of biodiversity in natural systems requires knowing what species are present in an ecosystem. We assessed fish communities in a stream using two methods, depletion‐based electrofishing and environmental DNA metabarcoding (eDNA) from water samples, to test the hypothesis that eDNA provides an alternative means of determining species richness and species identities for a natural ecosystem. In a northern Indiana stream, electrofishing yielded a direct estimate of 12 species and a mean estimated richness (Chao II estimator) of 16.6 species with a 95% confidence interval from 12.8 to 42.2. eDNA sampling detected an additional four species, congruent with the mean Chao II estimate from electrofishing. This increased detection rate for fish species between methods suggests that eDNA sampling can enhance estimation of fish fauna in flowing waters while having minimal sampling impacts on fish and their habitat. Modern genetic approaches therefore have the potential to transform our ability to build a more complete list of species for ecological investigations and inform management of aquatic ecosystems.     

生态系统服务功能及其生态经济价值评价

生态系统服务功能是指生态系统与生态过程所形成及所维持的人类赖以生存的自然环境条件与效用。它不仅为人类提供了食品、医药及其它生产生活原料,更重要的是维持了人类赖以生存的生命支持系统,维持生命物质的生物地化循环与水文循环,维持生物物种与遗传多样性,净化环境,维持大气化学的平衡与稳定。人们逐步认识到,生态服务功能是人类生存与现代文明的基础。近年来生态系统服务功能的研究已引起了人们的广泛重视,生态学家、经济学家纷纷探讨生态系统服务功能的内涵与定量评价方法,并已成为当前生态学与生态经济学研究的前沿课题。本文拟系统地分析生态系统服务功能的研究进展与趋势,生态系统服务功能价值的评估方法,并探讨生态系统服务功能及其与可持续发展研究的关系.     

Assessing freshwater use impacts in LCA: Part I—inventory modelling and characterisation factors for the main impact pathways

Background, aim and scope

Freshwater is a basic resource for humans; however, its link to human health is seldom related to lack of physical access to sufficient freshwater, but rather to poor distribution and access to safe water supplies. On the other hand, freshwater availability for aquatic ecosystems is often reduced due to competition with human uses, potentially leading to impacts on ecosystem quality. This paper summarises how this specific resource use can be dealt with in life cycle analysis (LCA).

Main features

The main quantifiable impact pathways linking freshwater use to the available supply are identified, leading to definition of the flows requiring quantification in the life cycle inventory (LCI).

Results

The LCI needs to distinguish between and quantify evaporative and non-evaporative uses of ‘blue’ and ‘green’ water, along with land use changes leading to changes in the availability of freshwater. Suitable indicators are suggested for the two main impact pathways [namely freshwater ecosystem impact (FEI) and freshwater depletion (FD)], and operational characterisation factors are provided for a range of countries and situations. For FEI, indicators relating current freshwater use to the available freshwater resources (with and without specific consideration of water ecosystem requirements) are suggested. For FD, the parameters required for evaluation of the commonly used abiotic depletion potentials are explored.

Discussion

An important value judgement when dealing with water use impacts is the omission or consideration of non-evaporative uses of water as impacting ecosystems. We suggest considering only evaporative uses as a default procedure, although more precautionary approaches (e.g. an ‘Egalitarian’ approach) may also include non-evaporative uses. Variation in seasonal river flows is not captured in the approach suggested for FEI, even though abstractions during droughts may have dramatic consequences for ecosystems; this has been considered beyond the scope of LCA.

Conclusions

The approach suggested here improves the representation of impacts associated with freshwater use in LCA. The information required by the approach is generally available to LCA practitioners

Recommendations and perspectives

The widespread use of the approach suggested here will require some development (and consensus) by LCI database developers. Linking the suggested midpoint indicators for FEI to a damage approach will require further analysis of the relationship between FEI indicators and ecosystem health.     

Paleolimnology: an important tool for effective ecosystem management

Effective management of aquatic resources requires long-term environmental data. However, because long-term observations are rarely available, indirect proxy methods must be used to substitute for these missing historical data sets. Major advances have been made in paleolimnology over the last decade, and many of these advances can be applied directly to integrated and cost-effective assessments of aquatic ecosystem health. This commentary uses the analogy of human health to argue that paleolimnological data provide information crucial to the decision-making processes of ecosystem managers.Keynote lecture, presented at the International Sumposium on Aquatic Ecosystem Health, Waterloo, Ontario, July 23, 1990.     

How Human Household Size Affects the Habitat of Black-and-White Snub-Nosed Monkeys (<Emphasis Type="Italic">Rhinopithecus bieti</Emphasis>) in Hongla Snow Mountain Nature Reserve in Tibet,China

Human impacts on the environment at local or regional scales largely depend on intrinsic characteristics of the population, such as household size, household number, and human population growth. These demographic factors can vary considerably among ethnic groups sharing similar ecological landscapes, yet the role of traditional cultural practices in shaping local environmental impacts is not well known for many parts of the world. We here quantify land-cover changes and their relation to the habitat of the endangered Rhinopithecus bieti in Tibet, in 2 areas populated by different ethnic groups (polyandrous Tibetans and monogamous Naxi) from 1986 to 2006. Results indicate that habitat of the monkey decreased greatly within our study area over the 20-yr period. Polyandrous and monogamous ethnic communities differed in household size, household number, population growth, and per capita and per household land use. The practice of polyandry by ethnic Tibetan appears to have reduced per capita resource consumption by reducing the growth of overall household number and increasing household size, which can mitigate the negative effects of higher human density and population growth on the environment. Ethnic Tibetan may also reduce land impacts by adhering to Buddhist customs and alternative, more sustainable means of livelihood. Accordingly, the protection of traditional cultural resources, such as polyandry and Buddhist beliefs, could be an effective way to aid biodiversity and environmental conservation efforts in this key ecosystem.     

Ecosystem Services in Life Cycle Assessment while Encouraging Techno‐Ecological Synergies

Life cycle assessment (LCA) has enabled consideration of environmental impacts beyond the narrow boundary of traditional engineering methods. This reduces the chance of shifting impacts outside the system boundary. However, sustainability also requires that supporting ecosystems are not adversely affected and remain capable of providing goods and services for supporting human activities. Conventional LCA does not account for this role of nature, and its metrics are best for comparing alternatives. These relative metrics do not provide information about absolute environmental sustainability, which requires comparison between the demand and supply of ecosystem services (ES). Techno‐ecological synergy (TES) is a framework to account for ES, and has been demonstrated by application to systems such as buildings and manufacturing activities that have narrow system boundaries. This article develops an approach for techno‐ecological synergy in life cycle assessment (TES‐LCA) by expanding the steps in conventional LCA to incorporate the demand and supply of ecosystem goods and services at multiple spatial scales. This enables calculation of absolute environmental sustainability metrics, and helps identify opportunities for improving a life cycle not just by reducing impacts, but also by restoring and protecting ecosystems. TES‐LCA of a biofuel life cycle demonstrates this approach by considering the ES of carbon sequestration, air quality regulation, and water provisioning. Results show that for the carbon sequestration ecosystem service, farming can be locally sustainable but unsustainable at the global or serviceshed scale. Air quality regulation is unsustainable at all scales, while water provisioning is sustainable at all scales for this study in the eastern part of the United States.     

全球环境变化对典型生态系统的影响研究:现状、挑战与发展趋势

随着全球环境变化和人类活动对生态系统影响的日益加深,生态系统结构和功能发生强烈变化,生态系统提供各类资源和服务的能力在显著下降。在这种背景下,全面认识生态系统的结构功能与全球环境变化的关系已成为当前生态学研究的热点之一。本文综述了全球环境变化对典型生态系统(包括森林生态系统、河口湿地生态系统、城市生态系统)影响以及全球环境变化适应的研究现状,分析研究面临的困难及挑战。在此基础上,提出对未来研究发展趋势的展望。在森林生态系统与全球环境变化研究上,未来应重视能更好模拟现实情景的、多因子、长期的全球环境变化控制试验,并注重不同生物地球化学循环之间的耦合作用。在湿地生态系统与全球环境变化研究上,未来应加强氮沉降、硫沉降及盐水入侵对湿地生态系统碳氮循环的影响,明晰滨海湿地的蓝碳功能,加强极端气候和人类干扰影响下湿地生态系统结构和功能变化及恢复力的研究。在城市生态系统与全球环境变化研究上,未来应深化城市生物地球化学循环机制研究,实现城市生态系统的人本需求侧重与转向,并开展典型地区长期、多要素综合响应研究。在全球环境变化适应研究上,未来应构架定量化、跨尺度的适应性评价体系,加强典型区域/部门的适应性研究以及适应策略实施的可行性研究,注重适应与减缓对策的关联研究及实施的风险评估。期望本综述为我国生态系统与全球环境变化研究提供一些参考。     

The Influence of Agricultural Trade and Livestock Production on the Global Phosphorus Cycle

Trends of increasing agricultural trade, increased concentration of livestock production systems, and increased human consumption of livestock products influence the distribution of nutrients across the global landscape. Phosphorus (P) represents a unique management challenge as we are rapidly depleting mineable reserves of this essential and non-renewable resource. At the same time, its overuse can lead to pollution of aquatic ecosystems. We analyzed the relative contributions of food crop, feed crop, and livestock product trade to P flows through agricultural soils for 12 countries from 1961 to 2007. Due to the intensification of agricultural production, average soil surface P balances more than tripled from 6 to 21 kg P ha⁻¹ between 1961 and 2007 for the 12 study countries. Consequently, countries that are primarily agricultural exporters carried increased risks for water pollution or, for Argentina, reduced soil fertility due to soil P mining to support exports. In 2007, nations imported food and feed from regions with higher apparent P fertilizer use efficiencies than if those crops were produced domestically. However, this was largely because imports were sourced from regions depleting soil P resources to support export crop production. In addition, the pattern of regional specialization and intensification of production systems also reduced the potential to recycle P resources, with greater implications for livestock production than crop production. In a globalizing world, it will be increasingly important to integrate biophysical constraints of our natural resources and environmental impacts of agricultural systems into trade policy and agreements and to develop mechanisms that move us closer to more equitable management of non-renewable resources such as phosphorus.