神农架山地河岸带连香树的种群结构与动态

以种群统计学和树木年代学的方法, 从年龄结构、生命表、径向生长和干扰史4个方面, 研究了神农架山地河岸带连香树 (Cercidiphyllum japonicum) 的种群结构与动态。结果显示:1) 连香树种群内幼龄个体比较充足, 但在长时段内更新时有断代, 多个局域种群有明显可辨的同生群 (年龄幅宽约为50a), 其发生年代在20世纪20年代和70年代, 高峰期则在40年代和90年代;2) 萌枝更新非常突出, 与种群年龄和群落盖度有显著相关 (r>0.6, p<0.05) ;3) 经20a以下和60~100a间两个死亡高峰以后, 种群可达生活力最优阶段, 180a以后出现衰老迹象, 生存曲线总体上介于DeeveyⅡ和Ⅲ型之间;4) 前30a连香树胸径的生长速率最快, 经2次生长释放后, 约在60a前后进入林冠层, 90~120a间进入成熟期前, 胸径分化最为剧烈;5) 干扰高峰年 (20世纪20年代、70年代和90年代) 与种群更新的高峰年大致吻合。这些结果表明, 个体生长发育特征与中长期的干扰对其种群结构与动态有重要影响。由于幼苗尤其是萌枝的的数量充足, 连香树种群在中短期内可以维持。     

神农架地区河岸带中领春木种群数量特征与空间分布格局

 东亚特有珍稀濒危植物领春木(Euptelea pleiospermum)在神农架地区集中分布于河岸带中。为初步探讨领春木在河岸带集中分布的成因和维持机制, 在神农架地区4条河流——沿渡河、香溪河、南河和堵河的河岸带, 共设置了30个样方(20 m × 30 m), 从种群的大小级结构、静态生命表、存活曲线、空间分布格局及其动态5个方面分析了神农架地区河岸带中领春木种群的数量特征与空间分布格局。结果表明: 1) 幼龄期个体缺乏, 中龄期个体相对丰富, 老龄期个体数量稀少。纺锤型的大小级结构表明种群属于衰退型, 但是以萌蘖为主要更新方式使其种群在较长一段时间内得以维持; 2)现存的Ⅰ、Ⅱ级个体数少, 导致静态生命表中Ⅰ、Ⅱ级个体死亡率出现负值, 自疏现象造成第Ⅳ级个体出现死亡率高峰, 由于接近实际寿命, 在第Ⅶ级死亡率达到最高; 3) 虽然其幼苗存活率较低, 但由于其幼树的存活率较高, 其存活曲线接近DeeveyⅠ型, 表明该地区河岸带的环境条件较适宜领春木种群的生长; 4) 空间分布格局总体为聚集分布, 这与大多数珍稀植物种群一致。人为干扰和自然环境影响其分布格局, 使种群由聚集分布向随机分布发展。因此使领春木种群在河岸带中沿海拔呈现“一带多岛”现象; 5) 从幼龄期到中龄期再到老龄期, 不同发育阶段的领春木种群的分布格局由聚集分布逐渐变为随机分布。但由于分布格局受种群本身生物学特性、自然环境因素(如坡向和海拔)和人为干扰的影响, 领春木在不同河岸带中的分布格局有所差异。     

Regeneration dynamics of subalpine fir (Abies fargesii) forest across the altitudinal range in the Shennongjia Mountains,central China

Aims Age structure and regeneration dynamics have been used to infer population response to environmental events and reconstruct forest development history. The aim of this study was to characterize and examine the differences of the age structure and regeneration dynamics of subalpine fir (Abies fargesii) forest across the altitudinal range in the north and south aspects in the Shennongjia Mountains, central China.Methods Ten plots (20×20 m) at each altitudinal zone (i.e. the low elevation, the middle elevation and the high elevation) were established in both the north and south aspects of the Shennongjia Mountains, central China. Dendroecological techniques were applied to obtain information about ages of the trees in the plots. The population age structure was analyzed to investigate the regeneration dynamics across the altitudinal range.Important findings Fir regeneration dynamics and age structure were similar in both aspects, and a unimodal population age structure was found at different altitudinal sites of both aspects, indicating that environmental factors might play an important role in shaping the regeneration dynamics and age structure of A. fargesii across its altitudinal range. There was a sustained recruitment during the 19th century, but the regeneration was rarer in the last century at low and midelevations. A significant greater number of fir seedlings and saplings recruited at high elevations in the last century, and fir tree density at high elevations was significantly higher than that at low elevations. Thus, the fir population at the high elevations showed a significant increase in recruitment and stem density in the last century, and we propose that the gradual infilling of fir seedlings might result in changes in regeneration dynamics and stand structure of the subalpine fir forest at high elevations in the Shennongjia Mountains, central China.     

神农架犀牛洞旧石器时代遗址发掘报告

本文记述犀牛洞旧石器遗址的发掘收获及初步研究成果。该遗址在我国南方旧石器时代遗址中是比较重要的。其文化性质为深入研究南方旧石器的文化类型增添了新材料。遗址海拔2102m,向人们显示出高海拔山地旧石器考古的良好前景。遗址动物群丰富,可使人们对动物群的演变与生态有更深的认识。     

神农架地区典型草本群落中的昆虫访花行为比较

对神农架地区不同海拔高度(1,000–2,600 m)的典型草本群落中的昆虫访花行为进行了初步的监测和统计。在9个样地中共观察到鳞翅目、膜翅目、双翅目11科昆虫访花, 访花者的类群在不同海拔高度的群落中有所不同, 但明显与植物群落的物种组成有关。对昆虫访花频率的监测发现, 不同物种组成的草本群落中, 所有昆虫访花的总频率和不同类群的昆虫访花频率都有差异, 正在开花的物种较多的群落中通常能吸引相对较多的访花者。同一种植物在不同的群落背景中受访频率差异显著, 如花被不甚显著的酸模(Rumex acetosa)在某些群落中未观察到访花者, 在另一些群落中却有昆虫频繁访问。而花被显著的血见愁老鹳草(Geranium henryi)在各群落中都有频繁的昆虫访问。一些植物(如广布野豌豆Vicia cracca)虽然在不同群落中都有昆虫访问, 但访花者类群却有较大差异。作者认为, 在植物群落中, 不同植物的花在吸引昆虫传粉方面存在着一定的相互作用, 在研究特定植物的虫媒传粉时应重视该植物种群所处的群落背景所起的作用。     

创新型实验教学项目建设的探索——土壤微生物分离实验

武汉大学生命科学学院微生物学实验教学中注重创新型实验教学项目的建设,创新型土壤微生物分离实验项目建设是培养学生创新能力的一次实践。从武汉大学校园和国家级自然保护区神农架采集土壤样品,分离土壤细菌、放线菌和霉菌。让学生了解土壤微生物数量测定的基本方法,学习了解平板计数的基本操作技术。在引申实验过程中又有机地结合与贯穿了微生物学的无菌操作技术、显微镜技术、纯培养技术、分离纯化技术等各项技术及最新的分子生物学研究方法和技术。本实验的创新点有三:首先,实验从室内延伸到室外;其次,从本科生的常规土壤微生物的分离实验衍生到科研实验(新菌种的分离、鉴定);最后,使共性教学衍生为个性化培养。     

神农架自然保护区非飞行哺乳动物的物种丰富度:沿海拔梯度的分布格局

于1999～2001年调查了神农架自然保护区6个地点不同栖息地的非飞行哺乳动物的物种丰富度。栖息地分为8类：原始林、择伐林（采伐枯立木）、次生林、灌木林、草地、常年性河流水溪、农田和人居住区。小型非飞行哺乳动物调查用捕鼠夹;大型非飞行哺乳动物调查主要根据皮张收购资料以及样线法和痕迹法;用10 m×10 m的样方调查林地树种丰富度。调查发现,神农架自然保护区有非飞行哺乳动物59种［不包括引进种梅花鹿（Cervus nippon）］。在同一海拔高度,原始林通常比择伐林和次生林的物种丰富度高,说明采伐严重降低了物种丰富度。对比同一栖息地不同海拔高度的物种丰富度,我们发现,在中海拔地段（800～1700 m）物种丰富度最高：如在原始林和次生林,海拔1700 m的东溪物种丰富度最高;在择伐林,海拔800 m的九冲物种丰富度最高。聚类分析显示,6个地点的哺乳动物物种组成可以分为两组：高海拔组（2100 m以上）和中低海拔组（1700 m以下）。各地点的哺乳动物物种组成与植被的垂直分布是一致的。各地点的物种丰富度与单位面积（100 m²）树种平均丰富度、栖息地类型数和海拔高度相关。3个环境变量间也是相关的：海拔高度对单位面积树种平均丰富度和栖息地类型数有重要影响。根据研究结果提出两点保护建议：第一,保护区的移民迁出和退耕还林工程应首先在物种丰富度最高的九冲进行,而后是东溪和下谷;第二,为了增加个体流和基因流,保护区东西两片相间的非保护区地带应划入保护区,建立栖息地廊道。     

神农架地区米心水青冈-曼青冈群落的结构与格局研究

 米心水青冈(Fagus engleriana)-曼青冈(Cyclobalanopsis oxyodon)常绿落叶阔叶混交群落是神农架山地植被垂直带谱的重要类型。通过分析乔木层结构及优势种的分布格局,探讨群落的特点及动态。结果表明,群落乔木层可分为3个亚层：第一亚层落叶阔叶树种占优势,势树种为米心水青冈;第二及第三亚层以常绿树种为主,优势种为曼青冈。应用偏离指数、Lloyd的平均拥挤度和聚块性指数及Morisita指数,在8个尺度下对米心水青冈及曼青冈两种优势树种进行格局分析,发现两者总体上均为聚集分布,米心水青冈的聚集强度高于曼青冈。按1～4cm, 4～8cm及8cm以上３个径级对曼青冈分布格局进行比较,各径级间聚集强度相似,没有自疏现象。由于米心水青冈及曼青冈占据乔木层不同的高度,且均不缺乏更新贮备,因此形成稳定共存的群落。     

GIS-based seasonal pattern of Rhinopithecus roxellana’s habitat selection in Shennongjia Reserve, Central China

Rhinopithecus roxellana’s habitat condition is directly related to its long-term survival and reproduction. Research, with large-scale, on R. roxellana’s habitat selection of seasonal changes is conducive to the protection and construction of its habitat, and it is essential protecting the rare species. Our research is based on the results of previous studies in biological and behavioral ecological field. With the support of GIS and RS technology, we conducted a lot of field investigations. In addition, we also took R. roxellana’s selection bias of seven kinds of ecological factors into consideration. Through the above efforts, we got a selection intensity distribution layer about R. roxellana’s habitat selection of seasonal changes. Our study shows that in spring, the area of weak intensity is 1507.96 hm² while less weak area is 33868.72 hm². The strong intensity area is 266 hm² while the less strong area is 36818.84 hm².
In summer, the area of weak intensity is 4683.4 hm² while less weak area is 28392.4 hm². The strong intensity area is 4078.52 hm² while the less strong area is 35307.2 hm².
In autumn, the area of weak intensity is 1972.08 hm² while less weak area is 33254.72 hm². The strong intensity area is 1516.84 hm² while the less strong area is 35717.88 hm².
In winter, the area of weak intensity is 542.76 hm² while less weak area is 28230.84 hm². The strong intensity area is 392.44 hm² while the less strong area is 43295.48 hm².
The results show that the most forestry areas of the Shennongjia Mt. lie in strong intensity area and these areas provides optimal habitat for the Snub-nosed Monkey.
The distribution layer analyses show that eastern part of the Shennongjia area is coincidence with the current natural distribution of the Snub-nosed Monkey, whereas north-western, south-western and southern part of the area is located in the weak intensity areas and is unfit for the Snub-nosed Monkey. In the central part, the strong intensity areas are fragmented by the highways and no Snub-nosed Monkey is found in this highly disturbed area. However, it is probably a potential habitat for the Snub-nosed Monkey.
Survival and reproduction of the Snub-nosed Monkey was ensured by large and continuous habitat in the eastern part of the Shennongjia Mt. Much effort is needed to intensify the connection of the fragmented central area of the Shennongjia Mt.     

Altitudinal Pattern of Plant Species Diversity in Shennongjia Mountains, Central China

One hundred and sixty plots, approximately every 100 m above sea level （a.s.1.） along an altitudinal gradient from 470 to 3 080 m a.s.1, at the southern and northern watershed of Mt. Shennongjia, China, were examined to determine the altitudinal pattern of plant species diversity. Mt. Shennongjia was found to have high plant species diversity, with 3 479 higher plants recorded. Partial correlation analysis and detrended canonical correspondence analysis （DCCA） based on plant species diversity revealed that altitude was the main factor affecting the spatial pattern of plant species diversity on Mt. Shennongjia and that canopy coverage of the arbor layer also had a considerable effect on plant species diversity. The DCCA based on species data of importance value further revealed that altitude gradient was the primary factor shaping the spatial pattern of plant species. In addition, the rule of the “mid-altitude bulge” was supported on Mt. Shennongjia. Plant species diversity was closely related to vegetation type and the transition zone usually had a higher diversity. Higher plant species diversity appeared in the mixed evergreen and deciduous broadleaved forest zone （900-1500 m a.s.1.） and its transition down to evergreen broadleaved forest zone or up to deciduous broadleaved forest zone. The largest plant species diversity in whole communities on Mt. Shennongjia lay at approximately 1 200 m a.s.1. Greatest tree diversity, shrub diversity, and grass diversity was found at approximately 1 500, 1 100, and 1 200 m a.s.l., respectively. The southern watershed showed higher plant species diversity than the northern watershed, with maximum plant species diversity at a higher altitude in the southern watershed than the northern watershed. These results indicate that Mt. Shennongjia shows characteristics of a transition region. The relationship between the altitudinal pattern of plant species diversity and the vegetation type in eastern China are also discussed and a hypothesis about the altitudinal pattern of plant species diversity in eastern China is proposed.