基于有害干扰的森林生态系统健康评价指标体系的构建

在分析国内外提出的众多森林生态系统健康评价指标的不足后,对评价指标进行研究和筛选。最终在森林生态系统健康评价指标体系的构建上提出了一个新的思路,即从森林火灾、林业有害生物、大气污染、人为有害干扰以及森林生态系统内部的增益干扰5个方面选取20个指标构建森林生态系统健康评价指标体系。其中森林火灾干扰包括平均降水量、平均气温、郁闭度、海拔、坡度、坡向、易燃树种的比例和林道距离8个指标,林业有害生物包括有害生物等级、危害程度和寄主树的比例3个指标,大气污染干扰通过叶片、土壤和污染物的分析测定,人为有害干扰包括森林经营措施、采伐措施和林下植被管理3个方面,而森林生态系统内部的增益干扰由物种多样性、群落结构和近自然度3个指标构成。同时对关键评价指标的意义进行了具体分析。此指标体系摒弃传统的评价观念,结合了近年来影响全国森林健康的几个重要原因,更能准确的反应目前森林生态系统的健康状况。研究思路和方法的提出在一定程度上可以丰富森林生态系统健康评价研究理论与方法体系。     

生态系统的脆弱性与退化生态系统

生态系统的脆弱性是一个含义广泛的概念,是生态系统内固有的特性,脆弱性只能在干扰的状态下才显现出来．而干扰（包括自然干扰和人为干扰）又是引起退化生态系统的原因,种类的入侵和消亡、种类组成的变化、生态系统的多样性和稳定性、生产力、生态位的分化及生态系统小环境变化则是研究退化生态系统形成和恢复的重要内容,本文探讨脆弱性与退化生态系统诸方面的关系以及在植被恢复上的应用．     

城市化地区湿地生态系统服务干扰评价——以深圳坪山河流域为例

城市化地区的湿地生态系统服务研究在湿地评价领域相对薄弱,现有的基于环境经济分析的评价模式也难以反映人为活动的干扰影响.本文从城市湿地生态系统服务的内涵确定和人为干扰方式辨识入手,建立表征干扰影响的评价因子体系,并运用层次决策分析法确定指标权重,采用两级式模糊综合评价模型考察人为活动干扰强度和干扰方式的空间分布异质性.以深圳市坪山河流域这一快速城市化典型地区为例进行试验性研究.结果显示：1）自然地理条件是影响坪山河流域湿地生态系统服务干扰的基础要素;2）南部丘陵山区以单一的植被覆被退化为主要干扰方式,干扰强度较低,但保护和管理不容忽视;3）北部平原宽谷地区的干扰强度普遍高于南部丘陵山区,且干扰方式多样化,干扰影响在空间上呈从干流上游至下游先增强、再减弱的趋势,与土地利用格局特征一致,但干扰方式的分布并不连续;4）模糊综合评价模型在湿地生态系统服务干扰评价中具有较好的实用性.     

林火干扰对森林生态系统土壤有机碳的影响研究进展

林火干扰是森林生态系统特殊而重要的生态因子,可改变生态系统的养分循环与能量传递。研究林火干扰对森林生态系统土壤有机碳的影响,有助于理解森林生态系统中土壤碳固持和碳循环过程,为制定科学合理的旨在减缓全球变化的林火管理策略具有重要意义。从4个方面阐述了林火干扰对森林生态系统土壤有机碳的影响及内在机制:分别从大尺度和小尺度两个方面阐述了林火干扰对土壤有机碳的影响及对森林生态系统碳循环与碳平衡的作用机制;探讨了不同林火干扰类型和林火干扰强度下,土壤活性有机碳对林火干扰的响应机制;阐明了林火干扰对土壤惰性有机碳的影响及作用机制;论述了林火干扰主要通过改变土壤有机碳的输入和输出过程进而影响土壤有机碳的稳定性及内在机制。最后提出了提高林火干扰对森林生态系统土壤有机碳影响定量化研究的4种路径选择:(1)全面比较研究不同林火干扰类型对土壤有机碳循环及其碳素再分配过程的功能特征;(2)进一步阐明林火干扰通过改变植被结构进而影响土壤生物群落结构,剖析土壤碳库循环的内在机制;(3)完善不同时空尺度下林火干扰对森林生态系统土壤碳库周转过程的定量化研究;(4)加强不同林火干扰类型土壤碳库稳定性差异的研究。     

海峡西岸经济区生态系统健康评价

基于活力、组织结构、恢复力、生态功能、人类健康等区域生态系统健康标准,综合考虑人为压力、响应措施等因素,构建了海峡西岸经济区(海西区)生态系统健康评价指标体系;针对区域生态系统健康的自然特性与人工特性,采用均方差法和层次分析法,确定了各指标权重;运用模糊综合评价法,建立了海西区生态系统健康评价模型.结果表明： 2008年,海西区生态系统健康状态优越,人为压力较轻,区域生态系统健康状况总体较好,但具有显著的空间差异;受固定资产投资、教育经费支出等响应指标的制约,部分地市生态系统健康状况劣于其健康状态.与1992年相比,2000和2008年海西区生态系统健康状况相对较优,驱动要素以经济活力、组织结构、人类健康、人口压力和投资调整等为主;但受建设用地扩张及其引起的自然景观减少、人类干扰增强等制约,2008年海西区生态系统健康状况劣于2000年.     

土壤生态系统微生物多样性-稳定性关系的思考

自20世纪50年代以来,生物多样性与生态系统稳定性的关系一直是生态学中重点讨论的理论问题之一.在当今人类活动对自然生态系统产生重大影响的情况下,全面理解生态系统多样性与稳定性的关系,有助于我们更好地应对环境变化和生物多样性丧失等生态问题.在陆地生态系统中,关注重点多集中在地上植物生态系统;而对地下生态系统,尤其是对微生物多样性与系统稳定性关系的研究尚重视不够.事实上,土壤微生物作为生命元素循环的驱动者,主导和参与地下生态系统中一系列重要生态过程,对土壤能否正常有序地执行各项生态功能至关重要.对土壤微生物多样性的研究,能使我们明确土壤中微生物对各种环境条件(包括自然和人为因素)变化的响应机制,更好地维持土壤生态系统的稳定性及其生态服务功能.本文在介绍土壤微生物多样性概念、研究方法、地下生态系统稳定性的基础上,重点讨论了土壤微生物多样性对土壤生态系统稳定性的影响,对多样性-稳定性关系在土壤微生物生态学中的应用进行了较为深入和全面的思考.作者提出,土壤微生物系统是一个动态变化的自组织系统,通过遗传来维持其组成和结构的相对稳定性,通过变异而适应外界干扰,共同构成土壤微生物系统的抵抗力(resistance)和恢复力(resilience),维护土壤生态系统的稳定性.今后土壤微生物多样性-稳定性关系的研究,需要注重地上与地下生态系统的结合与统一,借鉴宏观生态学理论来构建微生物生态学的理论框架,建立微生物多样性-稳定性关系的机理模型,从定性描述向定量表征方向发展.     

土壤微生物组与土壤健康

土壤健康在保障粮食安全和维持陆地生态系统功能方面起到举足轻重的作用,是农业可持续发展之本.土壤作为一个动态生命系统,其健康与土壤微生物组息息相关.土壤微生物组通过自身代谢参与元素循环和污染物降解等过程,同时在增强根际免疫,提高土壤肥力和作物产量方面扮演关键的角色,对土壤健康乃至人类健康具有重要意义.由于土壤生态系统的复杂性,目前对土壤微生物组与土壤健康关系的认知仍比较缺乏,不利于土壤健康的维持和提升.因此,本文围绕元素循环、污染消解和土传病害防控等三大土壤生态功能,系统梳理了土壤微生物组在维持和提升土壤健康中的重要作用,归纳了土壤微生物组作为评价土壤健康指标的研究进展,提出了利用土壤微生物组调控土壤健康的新途径.本文最后对土壤微生物组与土壤健康研究进行了展望,以期对维护土壤健康,改善土壤生态系统功能以及保障粮食安全提供科学依据.     

生态系统健康评价的研究进展

生态系统健康评价是环境管理和生态系统监控的基础,生态系统监控可促进生态系统健康评价。首先介绍了生态系统健康概念的产生,发展及其不同的内涵,并着重回顾和讨论了生态系统健康评价指标及其存在的问题,生态系统健康评价指标包括生态指标,物理化学指标,人类健康与社会经济指标3大类,生态指标是反映生态系统特征和状态的生物指标,它分为生态系统,群落和种群与个体等不同层次的指标或指标体系,物理化学指标是检测生态系统的非生物环境的指标。人类健康与社会经济指标着眼于生态系统对人类生存与社会发展的支持作用,采用经济参数和社会发展的环境压力指标等来衡量生态服务的质量与可持续性,根据其敏感程度和功能性,生态系统健康评价指标分为早期预警指标,适宜程度指标和诊断指标3类,一个完整的生态系统评价应包括上述3大类指标或指标体系,但在具体的评价实践中往往因评价目的和对象的不同而有所选择,生态系统健康评价目前有两个亟待解决的问题,如何有效确立评价标准与参照系以及如何正确区分人为压力和自然干扰。     

米亚罗地区亚高山针叶林在不同人为干扰条件下的土壤分形特征

分形理论是用于研究自然界中没有特征长度而又具有自相似性的图形和图像。它的发展为土壤等复杂体系的定量化研究提供了一种有效工具。以川西米亚罗地区几个不同强度人为干扰下的亚高山人工针叶林为对象,研究了其土壤颗粒和土壤微团聚体分形特征的变化,探讨了利用分形维数来表征人为干扰对亚高山人工针叶林土壤的影响,为研究亚高山针叶林生态系统恢复与重建提供了又一途径。     

中国森林健康生态风险评价

我国森林每年都在遭受诸如过度砍伐、火灾、病虫鼠害、酸雨、气象灾害等各种形式的干扰．这些干扰对我国森林生态系统的健康状况造成很大的威胁．因此,如何有效地管理我国的森林资源,特别是对森林的生态风险管理,提高森林生态系统抵御风险的能力,是森林生态系统健康研究和森林可持续管理的首要任务之一．森林健康生态风险评价是描述和评价人为活动、自然灾害和环境污染等胁迫因子对森林生态系统结构和功能、森林生态系统的健康状况产生不利影响的可能性和危害程度的评估,是森林资源管理的一个重要环节．以我国森林生态系统为例,探讨森林健康生态风险评价的研究方法,并以森林火灾、病虫害和酸雨为生态风险源,运用生态风险评价方法,分析了这些风险源对森林健康的主要危害,对我国森林健康的风险进行了综合评价,并提出不同森林风险区的管理策略．     

A microtiter plate procedure for evaluating fungal functional diversity on nitrogen substrates

Ascertaining the effects of anthropogenic disturbance on belowground diversity is of paramount importance because pollution from agricultural practices and industrialization are increasing worldwide. Although we have methods for evaluating soil microbial function with respect to carbon use our ability to evaluate use of other compounds is limited. Because N cycling is of paramount importance in ecosystem stability, evaluation of the ability of saprophytic soil fungi to use a variety of N sources would provide important information on possible alterations in ecosystem stability with disturbance. Herein is described a procedure (soil Nitrolog) for evaluating fungal functional diversity on a suite of 95 different N substrates. The soil Nitrolog procedure was evaluated by testing fungal functional diversity at two sites in Big Bend National Park (Chihuahuan Desert), differing in elevation and plant community composition. The soil Nitrolog procedure distinguished between the two sites based on overall use of the 95 N substrates. In addition the procedure detected differences in individual substrate use based on site specific plant compounds in response to changes in the amount of N entering these ecosystems from anthropogenic inputs.     

Functional composition of plant communities determines the spatial and temporal stability of soil microbial properties in a long‐term plant diversity experiment

Stable provisioning of ecosystem functions and services is crucial for human well‐being in a changing world. Two essential ecological components driving vital ecosystem functions in terrestrial ecosystems are plant diversity and soil microorganisms. In this study, we tracked soil microbial basal respiration and biomass over a time period of 12 years in a grassland biodiversity experiment (the Jena Experiment) and examined the role of plant diversity and plant functional group composition for the spatial and temporal stability of soil microbial properties (basal respiration and biomass) in bulk‐soil. Spatial and temporal stability were calculated as the inverse coefficient of variation (CV^?1) of soil microbial respiration and biomass measured from soil samples taken over space and time, respectively. We found that 1) plant species richness consistently increased soil microbial properties after a time lag of four years since the establishment of the experimental plots, 2) plant species richness had minor effects on the spatial stability of soil microbial properties, whereas 3) the functional composition of plant communities significantly affected spatial stability of soil microbial properties, with legumes and tall herbs reducing both the spatial stability of microbial respiration and biomass, while grasses increased the latter, and 4) the effect of plant diversity on temporal stability of soil microbial properties turned from being negative to neutral, suggesting that the recovery of soil microbial communities from former arable land‐use takes more than a decade. Our results highlight the importance of plant functional group composition for the spatial and temporal stability of soil microbial properties, and hence for microbially‐driven ecosystem processes, such as decomposition and element cycling, in temperate semi‐natural grassland.     

种、种的多样性及退化生态系统功能的恢复和维持研究

物种多样性是生态系统的重要特征并维持系统的功能支行,生物种和不同种类构成的群落为人类提供诸如营养物质循环、生物生产力、营养功能等形式的重要生态服务,特种多样性与生态系统抵御逆境和干扰的能力紧密相关,多样性的提高会增加系统的稳定性,与单个种和种类的数量相比,功能群和功能多样性对生态系统功能的影响效应要大得多,且易于被用来测度稳定性和预测群落变化,本文提出并探讨了种对生态系统功能作用的几种形式,理解物种多样性与生态系统的功能关系能指导退化生态系统恢复和维持其功能的实践活动,尤其为恢复的初始阶段进行群落的“种类组装”提供生态理论基础。     

Decline of soil microbial diversity does not influence the resistance and resilience of key soil microbial functional groups following a model disturbance

Analysing the consequences of the decrease in biodiversity for ecosystem functioning and stability has been a major concern in ecology. However, the impact of decline in soil microbial diversity on ecosystem sustainability remains largely unknown. This has been assessed for decomposition, which is insured by a large proportion of the soil microbial community, but not for more specialized and less diverse microbial groups. We determined the impact of a decrease in soil microbial diversity on the stability (i.e. resistance and resilience following disturbance) of two more specialized bacterial functional groups: denitrifiers and nitrite oxidizers. Soil microbial diversity was reduced using serial dilutions of a suspension obtained from a non-sterile soil that led to loss of species with low cell abundance, inoculation of microcosms of the same sterile soil with these serial dilutions, and subsequent incubation to enable establishment of similar cell abundances between treatments. The structure, cell abundance and activity of denitrifying and nitrite-oxidizing communities were characterized after incubation. Increasing dilution led to a progressive decrease in community diversity as assessed by the number of denaturating gradient gel electrophoresis (DGGE) bands, while community functioning was not impaired when cell abundance recovered after incubation. The microcosms were then subjected to a model disturbance: heating to 42 degrees C for 24 h. Abundance, structure and activity of each community were measured 3 h after completion of the disturbance to assess resistance, and after incubation of microcosms for 1 month to assess resilience. Resistance and resilience to the disturbance differed between the two communities, nitrite oxidizers being more affected. However, reducing the diversity of the two microbial functional groups did not impair either their resistance or their resilience following the disturbance. These results demonstrate the low sensitivity of the resistance and resilience of both microbial groups to diversity decline provided that cell abundance is similar between treatments.     

Native soil microbial amendments generate trade‐offs in plant productivity,diversity, and soil stability in coastal dune restorations

Given the important role that soil microbes play in structuring plant communities and mediating ecosystem functions, there is growing interest in harnessing microbial communities to restore degraded ecosystems. Dune restorations, in particular, may benefit from native soil amendments because microbial diversity and abundance are very low in unvegetated areas. In an outdoor mesocosm experiment simulating Texas Gulf Coast dune restorations, we tested how native soil microbial amendments and restored diversity of foundational grasses influenced three key restoration responses: plant performance, plant diversity (including the colonization of native forbs), and soil stability. We found that native microbial amendments increased plant diversity and have the potential to increase soil stability, but this came at the cost of decreased plant biomass. Our results suggest that soil enemies in the native microbial amendments increased plant diversity by decreasing the performance of the dominant grass species and that arbuscular mycorrhizal fungi in the native microbial amendments increased the density of fungal hyphae in the soil, which can increase soil stability. Depending on the goals of the restoration, native soil microbial amendments may be a simple and inexpensive method to provide restoration benefits.     

树种多样性对土壤微生物群落结构和元素生物地球化学循环的影响研究进展

森林是陆地生态系统的重要组成部分,其巨大的生产力和生态服务功能对人类的生存和发展至关重要。森林树种多样性增加能够显著提高森林生产力,关于树种多样性如何影响地下生物多样性及生态功能逐渐受到国内外学者的广泛关注。从土壤微生物及其介导的元素生物地球化学循环这一视角出发,综述了树种多样性对土壤细菌和真菌多样性、群落结构及功能的影响,提出需要进一步深入研究的方向。总体来说,树种多样性有利于增加土壤细菌生物量和多样性,是预测病原性真菌和菌根真菌多样性及群落结构的重要生物因子。树种多样性能增加土壤有机碳储量,增强森林土壤的甲烷氧化能力,并提高土壤磷周转速率及有效磷含量。关于树种多样性对森林土壤氮循环的影响需考虑多样性假说和质量比假说的相对贡献。今后应加强树种多样性对多个营养级之间相互作用的研究;关注树种多样性对生态系统多功能的影响;加强学科交叉,引入微生物种群动态模型和气候模型等模型预测方法,研究树种多样性对全球气候变化的应对机制,以期促进地上植物多样性与地下生态系统功能关系的研究,增强森林生态系统应对未来全球环境变化的能力。     

Bridging the gap between micro - and macro-scale perspectives on the role of microbial communities in global change ecology

In order to understand the role microbial communities play in mediating ecosystem response to disturbances it is essential to address the methodological and conceptual gap that exists between micro- and macro-scale perspectives in ecology. While there is little doubt microorganisms play a central role in ecosystem functioning and therefore in ecosystem response to global change-induced disturbance, our ability to investigate the exact nature of that role is limited by disciplinary and methodological differences among microbial and ecosystem ecologists. In this paper we present results from an interdisciplinary graduate-level seminar class focused on this topic. Through the medium of case studies in global change ecology (soil respiration, nitrogen cycling, plant species invasion and land use/cover change) we highlight differences in our respective approach to ecology and give examples where disciplinary perspective influences our interpretation of the system under study. Finally, we suggest a model for integrating perspectives that may lead to greater interdisciplinary collaboration and enhanced conceptual and mechanistic modeling of ecosystem response to disturbance.     

农牧交错带草地土壤剖面微生物总量、多样性和互作网络的垂直分布特征

【背景】草地土壤微生物是维持草地生态系统功能和稳定的关键要素之一,探寻微生物在土壤剖面的垂直分布特征和构建规律对于理解其在草地生态系统的作用至关重要。【目的】在80cm深的土壤剖面内,全面分析微生物的总量、多样性和物种间的相互作用网络表现出的垂直分布特征。【方法】基于内蒙古农牧交错带上典型草原土壤中原核微生物的定量和高通量测序数据,比较微生物的总量和多样性,使用分子生态网络方法(molecular ecological network approach,MENA)探究微生物相互作用网络的垂直变化。【结果】原核生物的总量和多样性随深度增加而逐渐降低,且群落结构变异沿土壤剖面逐渐增大。网络结构在表层最为复杂,微生物物种间联系紧密;随着深度的增加,微生物间紧密的关联会逐渐变稀疏,网络结构变得简单。此外,酸杆菌是当地土壤生态系统中的优势种群以及网络核心微生物物种,可能对土壤生态服务功能的稳定发挥具有重要的作用。【结论】原核微生物的总量、多样性和物种间的互作网络都表现出高度一致的垂直变化规律,即总量、多样性与深度成负相关,且其群落结构变异会逐渐扩大,同时微生物网络相关性会减弱。这些结果为我们提供了微生物动态变化的重要见解,对典型农牧交错带草地的生态保护具有一定的参考价值。     

A Coexisting Fungal-Bacterial Community Stabilizes Soil Decomposition Activity in a Microcosm Experiment

How diversity influences the stability of a community function is a major question in ecology. However, only limited empirical investigations of the diversity–stability relationship in soil microbial communities have been undertaken, despite the fundamental role of microbial communities in driving carbon and nutrient cycling in terrestrial ecosystems. In this study, we conducted a microcosm experiment to investigate the relationship between microbial diversity and stability of soil decomposition activities against changes in decomposition substrate quality by manipulating microbial community using selective biocides. We found that soil respiration rates and degradation enzyme activities by a coexisting fungal and bacterial community (a taxonomically diverse community) are more stable against changes in substrate quality (plant leaf materials) than those of a fungi-dominated or a bacteria-dominated community (less diverse community). Flexible changes in the microbial community composition and/or physiological state in the coexisting community against changes in substrate quality, as inferred by the soil lipid profile, may be the mechanism underlying this positive diversity–stability relationship. Our experiment demonstrated that the previously found positive diversity–stability relationship could also be valid in the soil microbial community. Our results also imply that the functional/taxonomic diversity and community ecology of soil microbes should be incorporated into the context of climate–ecosystem feedbacks. Changes in substrate quality, which could be induced by climate change, have impacts on decomposition process and carbon dioxide emission from soils, but such impacts may be attenuated by the functional diversity of soil microbial communities.     

火干扰对森林生态系统土壤呼吸组分的影响研究进展

土壤呼吸是陆地生态系统与大气碳交换的主要方式,主要分为自养呼吸和异养呼吸。土壤呼吸不仅是森林生态系统碳循环过程的关键环节,也是森林生态系统能量流动和物质循环的重要生态过程。火作为森林生态系统中一个重要的生态因子,可以在短时间内对土壤呼吸组分造成巨大的影响。火干扰对土壤呼吸组分的影响与火烧强度、火烧频率、火烧持续时间以及火后恢复等因子有关,通过影响植被的根系与组成、微生物群落数量与结构,凋落物的数量以及生态系统的环境和小气候等,进而对土壤呼吸产生影响。火干扰对土壤呼吸影响整体表现为火烧后土壤呼吸速率下降,在几个月至几年内恢复到火烧前水平,之后火继续对土壤呼吸产生影响长达数年至数十年。通过描述火烧强度、火烧频率以及火后恢复时间,阐述火干扰对土壤呼吸组分的直接影响,以及通过火后环境对土壤呼吸组分产生的间接影响,来揭示火干扰对森林生态系统土壤呼吸组分的影响。同时针对火干扰对土壤呼吸组分的影响进行以下3个方面的研究展望：（1）火后产生的黑碳对土壤呼吸组分的影响;（2）火后植被恢复对土壤呼吸组分产生的影响;（3）火后土壤呼吸组分的长期变化规律。