铜壁关自然保护区种子植物物种丰富度的海拔梯度格局——兼论物种密度的计算方法

利用对铜壁关自然保护区多次考察形成的种子植物数据库,结合通过GIS生成的区域数字高程模型(DEM)数据,分析了该区域种子植物物种丰富度及物种密度沿海拔梯度的变化特征。结果表明, 科、属、种的丰富度随海拔的升高,先增加后降低,在中海拔区域达到最大值,科、种的丰富度最大值出现在海拔1400~1800 m的范围内,属的丰富度最大值出现在1000~1400 m的海拔范围。科、属、种的密度随海拔升高先下降后上升,再下降后再上升;且最大值都出现在保护区最高海拔3000~3400 m的范围内。物种丰富度和物种密度分布格局明显受到海拔梯度的影响,海拔梯度综合了水热条件等诸多因素。铜壁关种子植物科、属、种水平上的物种丰富度的海拔分布格局符合中域效应假说;同时还对目前常用的计算物种密度的"对数模型"方法的普遍适用性提出质疑。     

小秦岭森林群落数量分类、排序及多样性垂直格局

采用分层取样的方法,沿小秦岭林区海拔梯度设立56块20 m×20 m样地,用多元回归树(MRT)方法对小秦岭森林群落进行分类,采用除趋势对应分析(DCA)进行排序,用广义可加模型(GAM)研究不同生活型物种多样性沿海拔梯度分布格局。结果表明:(1)56个样地进行MRT分类,经交叉验证并依据植物群落分类和命名原则,本区植物群落可分为5类;(2)样方DCA排序明确地揭示各群落类型生境分布范围,较好地反映小秦岭自然保护区森林群落与环境因子的关系;(3)不同生活型物种多样性指数随海拔梯度变化发生一定的波动,且呈现不同的多样性格局:丰富度指数中,乔木层呈显著的单峰分布格局,灌木层在中海拔段呈明显下降趋势,草本层随着海拔的升高总体呈下降趋势;Shannon-Wiener多样性指数中,不同生活型物种随海拔变化趋势与物种丰富度变化趋势大体相同;不同生活型物种的均匀度指数随海拔变化趋势较平缓。     

新疆天山南坡中段种子植物区系垂直分布格局分析

对植物多样性垂直分布格局及其维持机制的研究可以有效揭示植物物种多样性分布特征及其环境影响因子。本文通过野外调查、查阅标本并结合相关文献资料,对天山南坡中段种子植物区系沿海拔梯度的分布格局进行了系统研究。结果显示,在大区域尺度上,科属种的物种丰富度随海拔升高均呈先增加后减少的趋势,且最高值出现在中低海拔1900~2000 m处;不同生活型植物沿海拔梯度的变化格局有所不同,其中,乔木、一年生草本、藤本及寄生植物表现出随海拔升高物种丰富度逐渐降低的趋势,灌木、多年生草本及二年生草本植物物种丰富度则呈先增加后减少的变化趋势;从植物区系地理成分来看,世界分布所占的比重沿海拔梯度升高呈先增加后减少的趋势;温带地理成分所占的比重沿海拔梯度升高呈缓慢上升趋势;古地中海地理成分所占的比重沿海拔梯度升高呈先增加后减少然后再增加的变化趋势;热带地理成分所占的比重沿海拔升高呈逐渐下降的趋势;东亚地理成分所占的比重沿海拔梯度升高呈先增加后减少然后再增加的变化趋势。对该分布格局与当地干旱的气候条件及海拔梯度上热量和水分条件的变化相适应。     

云南横断山区蚤类物种丰富度与区系的垂直分布格局

为探讨横断山区蚤类物种丰富度与区系垂直分布格局的基本规律以及影响它们分布的主要生态因子,本文以云南西部横断山区18个山峰为主体,对海拔高度在1000–5000m之间已知分布的9科43属142种(亚种)蚤类的垂直分布资料进行综合整理和统计分析。结果显示:(1)蚤类的属丰富度、物种丰富度、特有种丰富度和特有度以及不同区系成分物种丰富度的垂直分布都呈现随海拔先增高后降低的单峰分布格局,最大峰值出现在中山海拔2500–3800m之间;(2)东洋和古北两区系成分物种构成比的垂直分布格局截然不同,前者随着海拔梯度的升高基本递减,后者则随着海拔的升高递增,垂直分布格局反映了它们沿纬度梯度分布的一般规律;(3)聚类分析将横断山9个不同海拔带的蚤类归为6个生态类型,反映出海拔高度、气候环境和森林植被等重要因素对蚤类分布的影响以及蚤类群落的组成、分布沿海拔梯度变化的一般规律,表达了蚤类分布与环境条件的统一性;(4)β多样性沿海拔梯度呈现为双峰形分布格局,两高峰值都反映出蚤类的组成和分布在不同气候环境和植被带之间的过渡与转变,说明β多样性垂直分布格局与海拔梯度上的气候和生境的变化程度有关。研究认为,中山地段物种丰富度高峰的形成主要是由于两大动、植物区系过渡区的边缘效应和山地水湿条件的影响。影响该区域蚤类垂直分布格局的综合因素有山体海拔高度、动植物区系过渡区的边缘效应、山地雨量分配特征、气候环境条件以及人们的生产活动等。     

广西猫儿山植物群落物种组成、群落结构及树种多样性的垂直分布格局

沿海拔梯度设置16个样地,对广西猫儿山植物群落物种多样性的垂直分布格局进行了初步研究。结果表明：(1)16个样地中共调查到乔木44科79属184种,其中常绿阔叶树121种、落叶阔叶树61种、针叶树2种;(2)随着海拔的上升,整个乔木层以及不同生活型的最大树高均呈显著下降趋势,而乔木树种的最大胸径、胸高断面积之和以及立木密度都呈现出先增大后减小的趋势;(3)物种丰富度在海拔1350m以下变化不明显,但1350m以上随着海拔的升高明显下降。在研究的海拔范围内,物种丰富度呈非常显著的单峰分布格局,最大的丰富度出现在中海拔群落中;(4)α多样性沿海拔梯度的变化趋势与物种丰富度相似,但没有后者显著。Shannon-Wiener指数(H’)和海拔之间有明显的负相关性,均匀度Pielou指数(E)在取样范围内并没有随着海拔梯度的变化表现出明显的规律;(5)1350m以下的相邻群落之间的Jaccard指数(CJ)大于1350m以上相邻群落之间的Jaccard指数,最小值出现在中海拔的植被过渡带。Cody指数也有类似的趋势,原因在于物种丰富度的变化;(6)在本研究的海拔范围内,海拔比坡度和坡向对群落的结构特征、物种丰富度以及α多样性的影响更大。而在局部尺度上,人为干扰以及小地形而导致的生境异质性对群落的物种多样性和结构特征有着重要的影响。     

地形对七姊妹山自然保护区植物丰富度及分布格局的影响

该研究以七姊妹山自然保护区40个(20×20m2)植物群落调查样方为基础,并采用回归分析和典型对应分析(CCA)的方法研究该区地形对植物物种丰富度及植物分布格局的影响,以明确海拔、坡度、坡向、坡位等地形因子的相对重要性,为该区植物多样性的保护和管理提供理论依据。结果表明:(1)七姊妹山自然保护区40个调查样地共有植物633种,隶属133科,316属,其中乔木118种,灌木150种,草本365种。(2)曲线回归方程拟合结果显示,七姊妹山自然保护区植物物种丰富度分别与海拔、坡度具有显著相关性,物种丰富度沿海拔梯度升高而增大,沿坡度梯度先减少后增大之后又减小。(3)从植物的生活型来看,在所有海拔段,乔木物种丰富度始终低于灌木和草本植物;在低、中低海拔地带,灌木物种丰富度均高于乔木和草本植物;而在中、高海拔地带草本植物物种丰富度较大且高于乔木和灌木。(4)CCA排序结果表明,地形因子对植物物种的分布具有显著影响按其影响强度排序为海拔坡度坡位坡向,说明海拔是影响该区植物物种分布最重要的地形因子。     

西双版纳种子植物物种多样性的垂直格局及机制

物种多样性海拔分布格局及其形成机制的研究是生物地理学和宏观生态学的重要议题之一。本文利用西双版纳植物专著资料, 结合高分辨率的地形和气候等数据, 探讨了面积、边界限制和现代气候对西双版纳野生种子植物物种丰富度及物种密度海拔分布格局的影响。结果表明: (1)物种丰富度呈单峰分布格局, 面积(81.9%)、边界限制(17.5%)和气候(60.0-69.3%)都不同程度地解释了物种丰富度的单峰格局; (2)利用幂函数种-面积关系计算的物种密度沿海拔大致呈减小的分布趋势, 气候的解释率降低为32.6-40.6%, 与边界限制无显著相关关系; (3)利用等面积高度带划分得到的物种密度沿海拔呈单峰变化趋势, 物种密度与边界限制无显著相关性, 但气候对物种密度的解释率为81.6-89.9%。研究结果有助于准确全面地理解物种多样性的海拔分布格局及其成因机制, 为西双版纳生物多样性保护提供理论支撑和实践指导。     

植物物种多样性的垂直分布格局

生物多样性沿环境梯度的变化趋势是生物多样性研究的一个重要议题,而海拔梯度包含了多种环境因子的梯度效应,因此研究生物多样性的海拔梯度格局对于揭示生物多样性的环境梯度变化规律具有重要意义。在不同的研究尺度,植物多样性沿海拔梯度具有不同的分布格局,而形成这种格局的因素有很大差异。本文从α多样性,β多样性和γ多样性三个尺度总结了植物物种多样性沿海拔梯度分布格局及其环境解释。α多样性沿海拔梯度的分布格局在不同生活型的物种之间差异很大,但对于木本植物来说,虽然也存在其他格局,但α多样性随海拔升高而降低是被广泛接受的一种格局。在一般情况下,β多样性随着海拔的升高而降低,并且对于不同生活型的物种,β多样性沿海拔梯度具有相似的分布格局。γ多样性沿海拔梯度具有两种分布格局：偏峰分布格局和显著的负相关格局;特有物种数往往随着海拔的升高而减少,而特有度则随着海拔的升高而增加。     

广东象头山国家级自然保护区兰科植物垂直分布格局

于2019～2022年对广东象头山国家级自然保护区内的兰科植物进行专项调查,记录兰科植物种类、数量、生活型、海拔、生境等信息,分析保护区内兰科植物的垂直分布格局,并根据《广东高等植物红色名录》和《国家重点保护野生植物名录》对各海拔高度兰花濒危等级的物种数量进行统计。结果显示：(1) 实地记录兰科植物33属48种,多数种类种群数量较少;(2) 随着海拔上升,各海拔梯度的兰科植物总种数和不同生活型的种数均呈现“中间高度膨胀型”分布特点,峰值在中低海拔区域;(3) 濒危物种主要集中在海拔200～500 m区间;(4) 相邻海拔段的兰科植物种类相似性系数较高,垂直梯度差异越大,相似性系数越小。低海拔地区可能由于人为干扰频繁,兰科植物物种多样性较低;中海拔物种多样性最丰富;高海拔地区生长环境较苛刻,物种数量较少。     

面积和中间膨胀效应对丽江地区种子植物物种丰富度垂直分布格局的影响

滇西北地区是我国三大特有物种分化中心之一。作者利用地方植物志资料,结合数值高程模型(DEM)数据,研究了云南丽江地区种子植物物种丰富度的垂直分布格局,并分析了面积和中间膨胀效应(mid-domaineffect)对该格局的影响。研究结果表明:随着海拔的升高,各海拔段面积呈先增加后下降的分布格局;物种丰富度、物种密度和中间膨胀效应的物种丰富度预测值在海拔梯度上均呈单峰型变化格局。面积和中间膨胀效应对丽江地区物种丰富度的垂直分布格局有着显著的影响。其中,面积起主要作用,对物种丰富度的变异解释百分率达80.2%,而中间膨胀效应的影响作用相对较小,仅占11.3%。     

Altitudinal patterns of seed plant richness in the Gaoligong Mountains, south-east Tibet, China

Elevational patterns of species richness and their underlying mechanisms have long been a controversial issue in biodiversity and biogeographical research, and several hypotheses have been proposed in the past decades. Local and regional studies have suggested that area and geometric constraint are two of major factors affecting the elevational pattern of species richness. In this study, using data of seed plants and their distribution ranges and a Digital Elevation Model data set, we explored altitudinal patterns of seed plant richness and quantified the effects of area and the mid-domain effect (MDE) on the richness patterns in a high mountain area, Gaoligong Mountains (ranging from 215 m to 5791 m a.s.l.) located in south-eastern Tibet, China. The results showed that richness and density (richness/log-transformed area) of seed plants at species, genus, and family levels all showed hump-shaped patterns along the altitudinal gradient. The altitudinal changes in richness of species with three different range sizes (< 500 m, 500–1500 m, and > 1500 m), species of different plant life-forms (trees, shrubs, and herbs), and endemic species further confirmed this finding. Analysis of Generalized Linear Model depicted that although the area of each elevational band was always in high correlation with the species richness, the MDE could explain 84.9%, 33.8%, 83.8%, and 84.5% of the total variation in richness for all species and the three species groups with different range sizes, respectively. This suggests that the MDE significantly influences the patterns of species richness and is likely be stronger for broad-ranged species than for narrow-ranged ones in the Gaoligong Mountains.     

澜沧县两栖动物多样性及海拔分布格局

海拔梯度综合了温度、降水等气候因子,是影响物种多样性分布格局的重要环境因子,两栖动物多样性及其海拔分布格局一直是生物地理学和生态学研究的重要内容。为了全面掌握云南澜沧县两栖动物多样性现状及海拔分布格局,在调查并掌握澜沧县两栖动物多样性本底数据的基础上,根据地形地貌和生境的不同,在澜沧县99个10km×10km有效网格中按照分层抽样的方法选取45个网格,每个网格设置3-5条样线,于2016-2017年开展野外调查。调查共发现两栖动物1842只,隶属于2目9科30属60种,以树蛙科为主,占两栖动物物种总数的28.3%,其中云南纤树蛙（Gracixalus yunnanensis）为新种,清迈泽陆蛙（Fejervarya qingmaiensis）为中国新纪录种;调查到中国特有种有15种,三有保护动物有25种,受威胁物种有19种,其中极危物种1种,濒危物种4种,易危物种14种;澜沧县两栖动物在海拔600-2400m范围内均有分布,其中,在海拔1800-2000m之间的范围内调查到的两栖动物物种数目和多度均较高,其次是在海拔1600-1800m和1200-1400m范围内;本次调查记录到的两栖动物物种数是历史记录物种数的3倍,属数比历史记录多了1倍,铃蟾科为新记录科;丰富度较高的网格尤其是丰富度在20以上的网格均处于中高海拔,海拔相对较低和较高的网格丰富度相对较低;两栖动物多样性科、属、种的丰富度在海拔梯度上分布格局不太一致,种丰富度的海拔分布格局大体呈双峰型,是由包括平均降水量、平均温度和植被覆盖指数等环境因子的综合作用,各因子与物种丰富度相关性从大到小依次为平均降水量 > 平均海拔=平均温度 > 植被覆盖指数 > 水网密度指数 > 样线距离水域的平均距离 > 植被类型数量。研究摸清了澜沧县两栖动物的多样性状况,分析了两栖动物多样性海拔分布格局,为澜沧县生物多样性保护提供基础数据。     

太白山南坡土壤种子库的物种组成与优势成分的垂直分布格局

本文通过野外植被调查和室内试验,采用物理方法从1220份土样中挑选种子,进行分类统计,研究了秦岭太白山南坡土壤种子库物种组成与优势成分的垂直格局。主要研究结果有：(1)从种子数量上看,在不同的海拔段,优势科不同;从物种数来看,海拔1600m和海拔2600m处的优势科数相对较多,有4个科;蔷薇科是种数最多的优势科。(2)桦木科的糙皮桦(Betula utilis)在16个海拔样地(海拔样地共有21个)中都是优势成分之一。糙皮桦和巴山冷杉(Abies fargesii)的种子储量在中等海拔呈现峰值;较高海拔处,糙皮桦作为优势成分之一所占的比例较大;而在低海拔则相对较小。(3)从种子库中种类组成上来看,草本种类占优势;从各样地土壤种子库的生活型组成并结合优势种类来看,乔木不仅在个体组成上占优势,大部分单优种类也是来自于乔木种类。灌木种类在土壤种子库中无论是种类组成,还是在个体组成上都没有表现出优势。本文为研究太白山南坡植物群落演替动态及其沿海拔梯度的变化提供了基础。     

Multi-scale altitudinal patterns in species richness of land snail communities in south-eastern France

Aim Species richness is an important feature of communities that varies along elevational gradients. Different patterns of distribution have been described in the literature for various taxonomic groups. This study aims to distinguish between species density and species richness and to describe, for land snails in south‐eastern France, the altitudinal patterns of both at different spatial scales. Location The study was conducted on five calcareous mountains in south‐eastern France (Etoile, Sainte Baume, Sainte Victoire, Ventoux and Queyras). Methods Stratified sampling according to vegetation and altitude was undertaken on five mountains, forming a composite altitudinal gradient ranging from 100 to 3100 m. Visual searching and analysis of turf samples were undertaken to collect land snail species. Species density is defined as the number of species found within quadrats of 25 m². Species richness is defined as the number of species found within an elevation zone. Different methods involving accumulation curves are used to describe the patterns in species richness. Elevation zones of different sizes are studied. Results Eighty‐seven species of land snails were recovered from 209 samples analysed during this study. Land snail species density, which can vary between 29 and 1 species per 25 m², decreases logarithmically with increasing altitude along the full gradient. However, on each mountain separately, only a linear decrease is observable. The climatic altitudinal gradient can explain a large part of this pattern, but the great variability suggests that other factors, such as heterogeneity of ground cover, also exert an influence on species density. The altitudinal pattern of species richness varies depending on the spatial resolution of the study. At fine resolution (altitudinal zones of 100 m) land snail species richness forms a plateau at altitudes below 1000 m, before decreasing with increasing altitude. At coarse resolution (altitudinal zones of 500 and 1000 m) the relationship becomes linear. Main conclusions This study reveals that land snail species density and land snail species richness form two different altitudinal patterns. Species density exhibits strong variability between sites of comparable altitude. A large number of samples seem necessary to study altitudinal patterns of species density. Species density decreases logarithmically with increasing altitude. Above a critical altitudinal threshold, this decrease lessens below the rate seen in the first 1500 m. Different methods exist to scale‐up species density to species richness but these often produce different patterns. In this study, the use of accumulation curves has yielded a pattern of species richness showing a plateau at low altitude, whereas simple plotting of known altitudinal ranges from single mountains would have produced stronger mid‐altitudinal peaks. This study shows that not only factors such as temperatures and habitat heterogeneity, but also an ecotone effect, are responsible for the observed patterns.     

Altitudinal distribution of native and alien plant species in roadside communities from central Argentina

Roadsides may homogenize the distribution of native species and act as corridors for the spread of alien taxa. We examined the variation in native and alien plant species richness and composition at two spatial scales defined by altitude and habitat type (edges and fill slopes), as well as the relationship between native and exotic species richness in roadside plant communities in mountains from central Argentina. Following a gradient from 1100 to 2200 m a.s.l. along a mountain road, plant species cover was recorded within sample plots of 30 m × 10 m systematically located at 100‐m altitude intervals on both roadside habitats. Although native species richness decreased with altitude and composition changed accordingly, the number of alien species peaked at both extremes of the elevation gradient and did not reflect an altitudinal replacement of chorological groups. The number of both native and alien species was higher in roadside edges, but a negative association between the richness of native and alien species occurred only on fill slopes, suggesting that roadside habitats differ in their susceptibility to plant species colonization and in the mechanisms driving native and alien species richness. Our results highlight the importance of altitude and roadside habitat as factors controlling plant species richness and composition along roadside communities in central Argentina. Although altitude acts as a filter for native plants, it apparently did not constrain the establishment of alien species along the studied roadsides, indicating that the influence of this road as a plant species corridor may increase with time, promoting the opportunities for aliens to expand their current distribution.     

泰山南北坡植物物种多样性垂直梯度格局的比较

以泰山南北坡14块样方的调查资料为基础,分析了泰山植物物种多样性沿海拔梯度的分布格局。结果表明:在相同海拔范围内,南坡物种丰富度大于北坡,泰山物种丰富度随海拔的升高而减少。整个群落及不同层次的物种多样性沿海拔梯度在泰山南北坡呈现不同的分布格局。在人为干扰程度低的情况下,北坡的群落物种丰富度在各个层次均较高,而多样性指数在各个层次不一样,北坡乔木层的多样性指数较南坡低,但灌木层和草本层则是北坡明显大于南坡。整体上,物种多样性指数与海拔的相关性,北坡要比南坡好。     

Precipitation controls seed bank size and its role in alpine meadow community regeneration with increasing altitude

The Tibetan Plateau has undergone significant climate warming in recent decades, and precipitation has also become increasingly variable. Much research has explored the effects of climate change on vegetation on this plateau. As potential vegetation buried in the soil, the soil seed bank is an important resource for ecosystem restoration and resilience. However, almost no studies have explored the effects of climate change on seed banks and the mechanisms of these effects. We used an altitudinal gradient to represent a decrease in temperature and collected soil seed bank samples from 27 alpine meadows (3,158–4,002 m) along this gradient. A structural equation model was used to explore the direct effects of mean annual precipitation (MAP) and mean annual temperature (MAT) on the soil seed bank and their indirect effects through aboveground vegetation and soil environmental factors. The species richness and abundance of the aboveground vegetation varied little along the altitudinal gradient, while the species richness and density of the seed bank decreased. The similarity between the seed bank and aboveground vegetation decreased with altitude; specifically, it decreased with MAP but was not related to MAT. The increase in MAP with increasing altitude directly decreased the species richness and density of the seed bank, while the increase in MAP and decrease in MAT with increasing altitude indirectly increased and decreased the species richness of the seed bank, respectively, by directly increasing and decreasing the species richness of the plant community. The size of the soil seed bank declined with increasing altitude. Increases in precipitation directly decreased the species richness and density and indirectly decreased the species richness of the seed bank with increasing elevation. The role of the seed bank in aboveground plant community regeneration decreases with increasing altitude, and this process is controlled by precipitation but not temperature.     

基于等面积高度带划分的贺兰山维管植物物种丰富度的海拔分布格局

山地植物物种丰富度海拔分布格局是生物多样性研究的热点之一。以往研究中一般将山体划分为等海拔间距的高度带, 以分析物种丰富度的垂直格局, 其缺陷在于因各高度带面积不相等而可比性下降。为消除面积不相等的影响, 作者利用数字高程数据(DEM, Digital Elevation Model)在地理信息系统(GIS)工具支持下, 尝试将贺兰山(海拔范围1,300–3,500 m)划分为等面积的数个高度带, 从而分析其物种丰富度的海拔格局。结果表明: (1) 贺兰山物种丰富度呈现为单峰式海拔格局, 峰值出现在海拔2,000 m附近。(2) 逐步回归分析显示, 坡度异质性是解释物种丰富度海拔分布格局的最优因子。高度带的坡度异质性越大, 意味着地形的起伏变化越大, 反映出生境类型越趋多样化, 从而可维持多个物种的共存。(3) 贺兰山植物物种丰富度在海拔2,000 m 附近达到峰值, 可能与植被演变历史、气候条件、地形复杂度、生态过渡带和中间膨胀效应的共同影响有关。(4) 对山体进行等面积划带, 可直接消除面积不相等带来的影响, 与等间距划带的方法相比, 尤其在物种海拔分布信息准确度较高时更具优势。