长期封育演替下典型草原植物群落生产力与多样性关系

封育是退化草地的重要恢复措施, 理解长期封育过程中草地群落生产力和植物多样性变化特征及两者间关系, 有助于草地植被的恢复管理与利用。该研究依托宁夏云雾山国家级自然保护区典型草原长期封育演替梯度, 选择持续放牧、封育9年、26年和34年的草地群落作为研究对象, 分析其地上生产力、物种多样性和功能多样性的变化特征及内在联系。结果表明, 封育显著提高典型草原植物群落的地上生产力、凋落物生物量、功能丰富度和功能离散度, 未改变草地群落的物种丰富度、Shannon-Wiener指数和功能均匀度, 但Simpson优势度指数和Pielou均匀度指数在长期封育(34年)后显著下降。此外, 封育对不同植物群落加权平均功能性状的影响存在差异。随机森林模型和方差分解结果显示, 群落加权平均功能性状对封育草地群落地上生产力变异的解释度高达70.70%, 其中植株高度是最主要的解释因子; 功能多样性的解释度为36.86%, 主要由功能丰富度贡献; 而物种多样性的解释度仅为14.72%。由此可见, 植物功能性状和功能多样性对草地群落地上生产力的贡献远高于物种多样性, 建议将其纳入植物群落恢复演替动态研究, 以便全面了解植物多样性与生态系统功能的关系, 为更好地实现生态恢复目标奠定基础。     

高寒矮嵩草草甸物种多样性与功能多样性对初级生产力的影响

自然生态系统中植物物种多样性是否随功能多样性变化而影响初级生产力的问题存在很大争议。在高寒矮嵩草草甸,对不同放牧强度、不同利用格局和土壤资源水平的4种生境（Ⅰ.畜圈：重度放牧、资源丰富;Ⅱ.牧道：中度放牧、资源适中;Ⅲ.人工草地：轻-中度放牧、资源贫乏;Ⅳ.封育草地：不放牧、资源贫乏）中物种多样性与功能多样性的变化及其对初级生产力的影响进行了研究。结果表明：物种多样性在牧道生境最高,符合中度干扰理论的预测;人工草地物种多样性低但功能多样性却最高;封育草地物种多样性和功能多样性均较高;物种多样性与地上生物量呈正相关,而功能多样性则与地上生物量呈负相关。表明功能多样性不随物种多样性而变化,二者可能在一定程度上是相互独立地作用于生产力的。群落生产力和生物多样性受生境资源、物种特征、放牧历史和放牧强度等因素的综合影响。     

功能多样性比物种多样性更好解释氮添加对高寒草地生物量的影响

为进一步了解氮添加条件下群落功能多样性如何驱动生物量变化, 该研究在位于天山山脉的巴音布鲁克高寒草地开展氮添加实验, 通过连续两年调查群落物种组成并测量常见物种的功能性状, 分析物种多样性、功能多样性及群落水平功能性状的响应模式及其在驱动生物量变化中的相对贡献。结果表明, 短期氮添加同时增加群落地上和地下生物量, 且地上生物量的增加比例高于地下生物量, 氮添加导致功能多样性降低但是物种多样性未发生显著变化; 氮添加增加群落水平上的植株高度和叶片碳含量, 但导致比叶面积、种子质量及叶片磷含量下降; 物种多样性对生物量变化解释非常有限, 而功能多样性与群落水平功能性状可以很好地解释生物量变化, 以上研究结果支持质量比假说。综上, 该研究表明功能多样性与群落水平功能性状比物种多样性对短期氮添加的响应更加迅速, 且两者在解释高寒草地群落生物量对氮添加的响应中起到关键作用。     

Nonlinear responses of productivity and diversity of alpine meadow communities to degradation

为了阐释青藏高原高寒草甸退化的关键生态过程, 该研究依托藏北高原草地生态系统研究站(那曲站), 设置不同退化梯度实验, 即对照、轻度退化、中度退化、重度退化和极度退化5个梯度, 探究群落生产力和物种多样性对不同退化强度的响应机制。结果表明: 1)随着退化程度不断加剧, 地上生物量呈现线性或非线性增加趋势, 在重度退化处理下, 地上生物量显著高于对照32.3%, 其中高山嵩草(Kobresia pygmaea)地上生物量呈非线性下降趋势, 而矮火绒草(Leontopodium nanum)地上生物量呈非线性增加趋势; 2)与地上生物量的响应模式相反, 随着退化程度加剧, 地下生物量与总生物量均呈现非线性降低趋势; 3)高寒草甸退化过程中, 物种辛普森指数、丰富度指数、香农多样性指数和均匀度指数均呈现非线性上升趋势。结构等式方程结果表明, 土壤碳含量和体积含水量与地下生物量均呈现显著的正相关关系。土壤碳含量、体积含水量和砾石质量比对地上生物量无显著影响, 土壤碳、氮含量与物种多样性指数呈现显著的负相关关系。研究认为地上生产力的变化不能很好地指示草地的退化程度, 建议今后研究应以可食性牧草和毒杂草等植物功能群的变化来衡量草地退化。     

高寒草甸退化过程中群落生产力和物种多样性的非线性响应机制研究

为了阐释青藏高原高寒草甸退化的关键生态过程, 该研究依托藏北高原草地生态系统研究站(那曲站), 设置不同退化梯度实验, 即对照、轻度退化、中度退化、重度退化和极度退化5个梯度, 探究群落生产力和物种多样性对不同退化强度的响应机制。结果表明: 1)随着退化程度不断加剧, 地上生物量呈现线性或非线性增加趋势, 在重度退化处理下, 地上生物量显著高于对照32.3%, 其中高山嵩草(Kobresia pygmaea)地上生物量呈非线性下降趋势, 而矮火绒草(Leontopodium nanum)地上生物量呈非线性增加趋势; 2)与地上生物量的响应模式相反, 随着退化程度加剧, 地下生物量与总生物量均呈现非线性降低趋势; 3)高寒草甸退化过程中, 物种辛普森指数、丰富度指数、香农多样性指数和均匀度指数均呈现非线性上升趋势。结构等式方程结果表明, 土壤碳含量和体积含水量与地下生物量均呈现显著的正相关关系。土壤碳含量、体积含水量和砾石质量比对地上生物量无显著影响, 土壤碳、氮含量与物种多样性指数呈现显著的负相关关系。研究认为地上生产力的变化不能很好地指示草地的退化程度, 建议今后研究应以可食性牧草和毒杂草等植物功能群的变化来衡量草地退化。     

调控措施对祁连山中度退化高寒草甸土壤的影响

研究不同调控措施(春季休牧、春季休牧-划破草皮、春季休牧-划破草皮-施肥、春季休牧-划破草皮-播种、春季休牧-划破草皮-施肥-播种)对祁连山中度退化高寒草甸植被、土壤理化性质和土壤微生物生物量的影响。结果表明: 各调控措施均显著增加了退化高寒草甸植被盖度以及地上、地下生物量,春季休牧-划破草皮-施肥与春季休牧-划破草皮-施肥-播种两种措施下植被物种丰富度显著增加,春季休牧-划破草皮-播种与春季休牧-划破草皮-施肥-播种措施下物种优势种为补播草种青海草地早熟禾。中度退化高寒草甸土壤(对照)pH和容重显著高于各调控措施样地,春季休牧-划破草皮-施肥-播种措施下土壤含水量、土壤有机碳、全氮、全钾含量及碳氮比、氮磷比均最高,分别为21.3%、22.30 g·kg^-1、2.77 g·kg^-1、19.93 g·kg^-1、8.3、3.5。春季休牧-划破草皮-施肥-播种措施下退化草地土壤微生物生物量氮、磷(分别为104.98和40.74 mg·kg^-1)显著高于其他措施,而退化草地在春季休牧-划破草皮-施肥措施下土壤微生物生物量碳(240.72 mg·kg^-1)显著高于其他措施。雷达图表明,调控措施对退化草地植被特征(地上、地下生物量)、土壤理化性质(含水量、有机碳、全氮、全磷、全钾)及土壤微生物生物量(碳、氮、磷)特征影响显著,且春季休牧-划破草皮-施肥-播种措施对研究区退化草地的修复效果最佳。     

氮添加对内蒙古退化草地植物群落多样性和生物量的影响

人为干扰及气候变化导致内蒙古草地发生了大面积退化, 氮添加是促进退化草地生产力恢复的一项重要措施。该文基于2011年建立的氮肥添加实验平台, 以3个不同退化程度(中度退化、重度退化、极度退化)草地群落为研究对象, 设置对照、10、20、30、40和50 g·m ^-2·a ^-1 6种氮添加处理, 分析氮添加对退化草地恢复过程中群落多样性和生物量的影响。结果表明: (1)氮添加降低了中度、重度退化草地恢复进程中物种丰富度和多样性, 对极度退化草地恢复进程中物种丰富度和多样性无明显影响。(2)氮添加促进了3个不同退化程度草地恢复进程中群落地上生物量的增加。(3)氮添加显著增加了群落中禾草的地上生物量及其在群落地上生物量中所占的比例, 降低了杂类草在群落地上生物量中的比例, 但对杂类草地上生物量无显著影响。研究表明在利用施肥措施治理退化草地的过程中, 需要充分考虑草地退化程度以及由氮添加引起的群落多样性和生产力的改变对草地生态系统功能的影响。     

Effects of nitrogen addition on the plant diversity and biomass of degraded grasslands of Nei Mongol,China

人为干扰及气候变化导致内蒙古草地发生了大面积退化, 氮添加是促进退化草地生产力恢复的一项重要措施。该文基于2011年建立的氮肥添加实验平台, 以3个不同退化程度(中度退化、重度退化、极度退化)草地群落为研究对象, 设置对照、10、20、30、40和50 g·m ^-2·a ^-1 6种氮添加处理, 分析氮添加对退化草地恢复过程中群落多样性和生物量的影响。结果表明: (1)氮添加降低了中度、重度退化草地恢复进程中物种丰富度和多样性, 对极度退化草地恢复进程中物种丰富度和多样性无明显影响。(2)氮添加促进了3个不同退化程度草地恢复进程中群落地上生物量的增加。(3)氮添加显著增加了群落中禾草的地上生物量及其在群落地上生物量中所占的比例, 降低了杂类草在群落地上生物量中的比例, 但对杂类草地上生物量无显著影响。研究表明在利用施肥措施治理退化草地的过程中, 需要充分考虑草地退化程度以及由氮添加引起的群落多样性和生产力的改变对草地生态系统功能的影响。     

红松洼自然保护区草地群落物种多样性和土壤肥力与地上生物量的相关性研究

物种多样性与生物量之间的关系已经成为现代生态学研究的重要问题, 而土壤肥力也是影响生物量的重要因素。 文章以红松洼自然保护区为例, 通过对红松洼自然保护区核心区和实验区植物的种类、数量、高度、盖度、物候期的实地采样调查, 以及对两区土壤的含水量、有机质含量、全氮含量、全磷含量的实地采样调查, 系统地分析了红松洼自然保护区植物物种多样性、土壤肥力与草地地上生物量三者之间的相关性。结果表明, 草地群落植物物种多样性与草地地上生物量呈显著正相关(P＜0.05), 植物物种多样性指数、均匀度指数与草地地上生物量也呈显著的正相关(P＜0.05), 土壤肥力中土壤水分、土壤全氮含量与草地地上生物量之间并无显著相关性(P＞0.05), 但是与土壤有机质含量呈显著的正相关性(P＜0.05), 与土壤全磷呈显著的负相关性(r＜0)。揭示可以通过提高植物物种多样性和土壤有机质含量来提高草地地上生物量。     

拉萨地区居民点周边典型湿草甸湿地植被与土壤特征分析

通过典型样地调查及室内分析, 对拉萨地区居民点周边湿草甸植物群落多样性、生产力以及土壤养分特征等进行了研究。结果表明, 在14个样地的调查中共记录到34种植物, 植物群落物种丰富度、均匀度以及Shannon-Wiener多样性指数分别在为4—11个•0.25m-2、0.84—0.95、1.3—2.5之间; 群落地上生物量在173.33—648.00 g•m-2之间, 地下生物量在1154.08—10013.75 g•m-2之间; 表层土壤有机质、全氮、速效氮及速效磷含量分别为21.33—128.26 g•kg-1、1.83—11.13 g•kg-1、59.55—247.03 mg•kg-1、2.40—16.10 mg•kg-1。群落物种丰富度及Shannon-Wiener多样性指数与人口数量、土壤速效磷含量显著相关; 群落地下生物量及生物量分配比例与人口数、速效磷含量显著相关; 有机质及全氮含量与海拔及土壤含水量显著相关, 而速效磷含量与人口数显著相关。在该区湿草甸湿地的保护与恢复过程中, 植物群落生物量分配特征、Shannon-Wiener多样性指数以及丰富度指数、土壤速效磷含量等指标可以作为湿草甸湿地生态系统监测与评价的敏感指标。     

Assessing biotic and abiotic effects on forest productivity in three temperate forests

1. It is well understood that biotic and abiotic variables influence forest productivity. However, in regard to temperate forests, the relative contributions of the aforementioned drivers to biomass demographic processes (i.e., the growth rates of the survivors and recruits) have not received a great deal of attention. Thus, this study focused on the identification of the relative influencing effects of biotic and abiotic variables in the demographic biomass processes of temperate forests.
2. This study was conducted in the Changbai Mountain Nature Reserve, in northeastern China. Based on the observational data collected from three 5.2‐hectare forest plots, the annual above‐ground biomass (AGB) increment (productivity) of the surviving trees, recruits, and the total tree community (survivors + recruits) were estimated. Then, the changes in the forest productivity in response to biotic variables (including species diversity, structural diversity, and density variables) along with abiotic variables (including topographic and soil variables) were evaluated using linear mixed‐effect models.
3. This study determined that the biotic variables regulated the variabilities in productivity. Density variables were the most critical drivers of the annual AGB increments of the surviving trees and total tree community. Structural diversity enhanced the annual AGB increments of the recruits, but diminished the annual AGB increments of the surviving trees and the total tree community. Species diversity and abiotic variables did not have impacts on the productivity in the examined forest plots.
4. The results highlighted the important roles of forest density and structural diversity in the biomass demographic processes of temperate forests. The surviving and recruit trees were found to respond differently to the biotic variables, which suggested that the asymmetric competition had shaped the productivity dynamics in forests. Therefore, the findings emphasized the need to consider the demographic processes of forest productivity to better understand the functions of forests.

     

树种多样性和土壤微生物多样性对人工林生产力的影响

林分生产力通常会随着树种多样性增加而增加,但不同营养级生物多样性以及树种和土壤微生物多样性之间的相互作用如何影响生产力目前尚不清楚。以亚热带不同丰富度和树种组成的人工林为研究对象,从物种、功能性状、遗传三个维度的树种多样性以及土壤真菌和细菌系统发育多样性,探究了中国亚热带人工林树种多样性和土壤微生物多样性对林分生产力的影响。研究发现,林分生产力随树种功能多样性(FD)(P<0.001)、比叶面积群落加权均值(CWM-SLA)(P<0.01)、树种系统发育多样性(PD)(P<0.05)和土壤真菌多样性(PDF)(P<0.01)的增加而显著增加,分别解释了林分生产力总变异的12.86%、6.80%、3.67%和3.08%。FD和CWM-SLA可分别通过增加土壤真菌、细菌多样性而间接提高林分生产力。研究结果表明多营养级生物多样性是维持高水平林分生产力的基础,树种多样性和土壤微生物多样性之间的自上而下的级联效应在调节生态系统生产力方面发挥着重要作用。     

Soil fungal pathogens and the relationship between plant diversity and productivity

One robust result from many small-scale experiments has been that plant community productivity often increases with increasing plant diversity. Most frequently, resource-based or competitive interactions are thought to drive this positive diversity-productivity relationship. Here, we ask whether suppression of plant productivity by soil fungal pathogens might also drive a positive diversity-productivity relationship. We created plant assemblages that varied in diversity and crossed this with a ± soil fungicide treatment. In control (non-fungicide treated) assemblages there was a strong positive relationship between plant diversity and above-ground plant biomass. However, in fungicide-treated assemblages this relationship disappeared. This occurred because fungicide increased plant production by an average of 141% at the lower ends of diversity but boosted production by an average of only 33% at the higher ends of diversity, essentially flattening the diversity-productivity curve. These results suggest that soil pathogens might be a heretofore unappreciated driver of diversity-productivity relationships.     

短花针茅荒漠草原物种多样性及生产力对长期不同放牧强度的响应

以内蒙古四子王旗短花针茅(Stipa breviflora)荒漠草原为研究对象,从植物个体尺度入手,通过2016年野外群落调查试验,对荒漠草原不同放牧处理[载畜率分别为0(CK)、0.91(LG)、1.82(MG)、2.71(HG)羊/(hm2·a-1)]下的物种组成、植物多样性与生产力的关系进行分析,以揭示荒漠草原群落中的物种组成、物种多样性及其功能群多样性对不同载畜率的响应机制。结果表明:(1)对照区的植物种最多,有13科30种,轻度放牧区只比对照区少野韭(Allium ramosum)1种植物,而中度放牧区和重度放牧区的植物种分别较对照区减少了30%和40%,其中减少的物种大多属于多年生杂类草与多年生根茎禾草两大功能群。(2)多年生丛生禾草在植物群落中占比始终最大(29%~78%),且随着载畜率的增加而增加,而其他功能群均随载畜率增加呈减小的趋势。(3)两种多样性指数中,除了功能群多样性的Margalef丰富度指数,其他多样性指数均在对照区达到最大值,且大小依次为对照轻度中度重度放牧区。(4)物种多样性的3个α多样性指数与草地生产力存在显著正相关关系,功能群多样性指数则与生产力无相关关系。研究认为,长期放牧使得荒漠草原群落结构趋于简单化,使多年生丛生禾草形成优势单种;且载畜率的增加使得短花针茅荒漠草原植物的多样性及生产力均显著下降,高水平的多样性会导致高水平的草地生产力,比较2种多样性指数指标,物种多样性指标对荒漠草原生产力的贡献更大。     

Primary productivity is weakly related to floristic alpha and beta diversity across Australia

Aim Ecosystem functions such as productivity may be influenced not only by the biological diversity at each location (α‐diversity) but also by the biological turnover between locations (β‐diversity). We perform a continental‐scale test of the strength and direction of relationships between gross primary productivity (GPP) and both α‐ and β‐diversity. Location Continental Australia. Methods Species occurrence records were used to quantify the taxonomic α‐diversity of vascular plants in approximately 11,000 1 km × 1 km grid cells across Australia, and to calculate the average β‐diversity within a 10‐km radius around each cell. The magnitude and variability of monthly, MODIS‐derived remotely sensed GPP (2001–12) were summarized for continental Australia, as were rainfall and temperature over the same period. Generalized additive models were then used to test whether the magnitude or variability of GPP were distinctly influenced by either biodiversity measure, over and above the influence of environmental conditions. Results Precipitation and temperature explained large proportions of deviance in the magnitude (75.6%) and variability (38.3%) of GPP across the Australian continent. GPP was marginally more strongly related to species richness than it was to species turnover. However, neither diversity measure provided substantial increases in the explanatory power of GPP models over and above that of environment‐only models (always < 1%). Main conclusions The relationship between primary productivity and taxonomic α‐ and β‐diversity was weak for the Australian flora. Our findings question the generality of key assumptions, predictions and results in the literature regarding the strength of empirical relationships between productivity and biodiversity across multiple biological levels (α‐, β‐ and γ‐diversity) at macroecological scales.     

Different categories of biodiversity explain productivity variation after fertilization in a Tibetan alpine meadow community

The relationship between productivity and biodiversity has long been an important issue in ecological research. However, in recent decades, most ecologists have primarily focused on species diversity while paying little attention to functional diversity and phylogenetic diversity (PD), especially in alpine meadow communities following fertilization. In this study, a fertilization experiment involving the addition of nitrogen, phosphorus, and a mixture of both was implemented in an alpine meadow on the Tibetan Plateau. Species diversity, functional diversity, and PD were measured, and the responses of these parameters to the variation in productivity were analyzed. We found that the productivity of alpine plant communities was colimited by N and P, with N being the principal and P being the secondary limiting nutrient. Our results supported the prediction of both the mass ratio hypothesis and niche complementarity hypothesis in fertilized communities, but these hypotheses were not mutually exclusive. The combination of different aspects of biodiversity not only provides a crucial tool to explain the variation in productivity and to understand the underlying mechanisms but also plays an important role in predicting the variation in productivity of alpine meadow communities, which are sensitive to nutrient enrichment in the context of global change.     

Reconsidering diversity–productivity relationships: directness of productivity estimates matters

Despite extensive research efforts, the controversy over diversity–productivity (D–P) patterns in natural communities still looms large. Recent meta‐analyses suggest that unimodal D–P relationships tend to pre‐dominate in plant studies, while positively linear relationships are more common in animal studies. These patterns, however, are based on studies in which productivity is estimated either directly, based on the biomass or energy of the studied organisms, or indirectly, according to the productivity of lower trophic levels, and various surrogates. Our analysis shows that the distribution of D–P patterns is sensitive to the directness of productivity estimates in animal studies but not in plant studies. Analysis of D–P patterns should be based on direct productivity estimates of the studied organisms, especially in comparative meta‐analyses of communities from multiple trophic levels, where productivity is often affected nonlinearly by indirect factors or when complex feedback interactions are expected between productivity and diversity.     

南亚热带常绿阔叶林树木多样性与生物量和生产力的关联及其影响因素

生物多样性和生态系统功能的关系直接或间接地影响着生产力, 是生态学研究的关键问题。本研究旨在定量探讨亚热带自然林演替后期森林生态系统树木多样性与生物量或生产力的关系。本研究基于中国南亚热带长期永久性样地的群落调查数据以及地形和土壤养分数据, 分析了南亚热带常绿阔叶林树木多样性与生物量和生产力的关联及其影响因素。相关性分析结果表明, 物种多样性与生物量呈显著负相关, 与生产力呈显著正相关; 结构多样性与生物量呈显著正相关, 与生产力呈显著负相关。此外, 不同环境因子对多样性、生物量和生产力的影响具有显著差异, 其中土壤含水量对生产力有显著影响, 物种多样性指标与部分地形和土壤因子均有相关性, 而群落结构多样性指标与土壤因子的相关性更强。方差分解结果表明, 结构多样性对生物量和生产力的单独效应的解释率最大, 分别为35.39%和5.21%; 其次是结构多样性和物种多样性的共同效应, 对生物量和生产力的解释率分别为13.66%和3.53%; 地形和土壤因子的解释率较小。同时, 结构方程结果也表明, 结构多样性对生物量有较强的直接正影响; 生物量对生产力有强烈的直接负影响, 结构多样性通过增加生物量明显地减少了生产力; 土壤和地形因子主要是通过物种和结构多样性间接影响生物量和生产力。综上, 本研究认为在南亚热带森林演替顶极群落中, 群落结构复杂性和物种多样性的提高对促进群落生产力和生物量具有重要作用。