2000-2016年秦岭山地植被覆盖变化地形分异效应

利用2000-2016年MODIS NDVI数据,采用趋势分析及地形差异修正法,探讨秦岭山地植被覆盖变化在南北坡、不同海拔以及不同坡度坡向下的空间分异性。结果表明：近17年来,秦岭山地植被覆盖度良好,整体呈上升趋势,南北坡、不同海拔、不同坡度、不同坡向下植被覆盖度有所差异,植被变化趋势也不同。（1）就南北坡而言,近17年来秦岭南坡植被覆盖度上升趋势大于北坡,南坡植被覆盖以上升趋势为主,而北坡以稳定为主。（2）不同的海拔高度上秦岭山地植被覆盖变化在存在分异性：低海拔区域呈减少趋势,中海拔区呈明显的上升趋势,2000 m以上的高海拔区域北坡的植被覆盖度较为稳定,而南坡的2500到3100 m区域内有较明显的减小趋势。（3）从坡度来看,随着坡度的增加秦岭山地植被覆盖度由减少转为增加再转为稳定,南北坡植被变化分异性不明显。（4）不同坡向上,秦岭南北坡植被覆盖度变化差异明显,由阴坡转为阳坡时,北坡植被覆盖有明显的增长趋势,而南坡则不明显,植被覆盖度减小区在南北坡的分布呈相反趋势,分别分布在南坡的阳坡以及北坡的阴坡。     

山西恒山温带草原与暖温带落叶阔叶林交错区植被生态研究

在中国植被分区上,山西恒山是温带草原地带与暖温带落叶阔叶林地带的交错区.采用TWINSPAN分类和DCA排序相结合的方法,对恒山南北坡植被类型进行了比较研究.TWINSPAN分类结果将南北坡的植被分别划分为16个群丛和20个群丛,分别隶属于16个和20个群系.DCA排序较好的印证了其分类结果：DCA排序第一轴反映海拔、温度的变化,南坡植被随海拔的升高,从耐旱的山蒿灌丛向寒温性的针叶林过渡,北坡由旱生的长芒草草原也向寒温性的针叶林过渡; 第二轴反映湿度的变化,排序轴从上到下,南坡由低海拔的山蒿群丛向高海拔的华北落叶松群丛,北坡是由长芒草、碱茅群丛向青杨群丛过渡.DCA排序结果显示,南北坡基带植被的群丛组成迥然不同,南坡基带为山蒿群丛、三裂叶绣线菊-山蒿＋赖草群丛、虎榛子-披针叶苔草群丛,是落叶阔叶林破坏后形成的次生植被类型;北坡基带为长芒草群丛、碱茅＋千里光群丛、三裂叶绣线菊-硬质早熟禾群丛、山菊＋硬质早熟禾群丛,具有典型的草原植被特征,这与它们所处的植被带有较高的吻合度.南北坡随海拔升高,植被类型表现出明显的趋同性.对南北坡群系的比较结果表明：有4个群系为南北坡共有,但群丛数量存在较大的差异,三裂叶绣线菊群系、山蒿群系在南坡的群丛数要比北坡多,披针叶苔草群系在北坡的群丛数要比南坡多,华北落叶松群系分布大致相同.     

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。     

南岭国家级自然保护区蝴蝶多样性与区系研究

广东南岭国家级自然保护区位于南岭山脉中段的核心区域,在生物进化史中具有特殊的地位。对栖息微环境变化敏感的蝶类是生态环境变化的指示物种,对其进行多样性和区系的研究,可为南岭蝶类资源的保护和利用等提供科学依据。于1990-1997年,2006-2016年连续多次对该保护区蝶类进行了调查,结果显示:共记录蝴蝶11科218属501种,是国内诸保护区中蝴蝶种数最多的。分布在东洋区的蝴蝶共377种,占蝶类种数的75.2%,古北区94种,占18.8%,其它跨区系分布的只有30种,属东洋区主导的分布型;国内分布于华南、西南、华中3区的蝴蝶共391种(78.04%),其它分布区种类少,这些说明南岭蝴蝶与南岭植物一样主要属亚热带成分。从自然保护区尺度的蝴蝶区系相似性比较看出,种类数和区系相似性都随着离南岭的距离增大而减少,与海南尖峰岭相比热带成分明显减少,这些说明南岭蝴蝶组分不仅有热带向亚热带过渡的特点,而且明显表现出以南岭为核心向周边扩散,暗示了南岭中段可能为我国蝴蝶的起源和分化中心。弄蝶是蝶类中系统发育过程中最古老的类群,该保护区弄蝶达132种,占我国弄蝶种数的35.68%,这可能与丰富而古老的植物区系紧密相关;黛眼蝶属(幼虫以竹子为寄主)有28种,居国内各保护区之首,这与南岭山地丰富的竹类资源有关,这些表明植物与蝴蝶间密切的协同进化关系。     

福建黄岗山东南坡和西北坡乔木物种多样性及群落特征的垂直变化

利用福建黄岗山东南坡30个样方和西北坡13个样方的资料,研究该地区乔木物种丰富度的垂直变化;东南坡共记录到乔木物种151种,隶属于42科73属;西北坡102种,隶属于32科54属。两坡面的乔木树种组成相差不大。物种丰富度随海拔的变化趋势是：随海拔升高,科、属、种的数量呈下降的趋势;东南坡科、属、种的数量在海拔800—1000m达到最大值,西北坡在海拔1500—1600m达到最大值。东南坡乔木物种Shannon—Wiener指数(H’)与海拔呈负相关;西北坡在海拔1200—1800m范围内H’高于东南坡;Screnson指数(IAc)在不同植被类型交替时出现上下波动,从常绿阔叶林向针阔混交林转化时,物种更替强烈,Screnson指数明显下降。乔木物种生长特征的分析表明,最大树高(Hmax)和最大胸径(DBHmax)出现在中海拔,在相同海拔范围内西北坡的Hmax和DBHmax高于东南坡;东南坡Hmax和DBHmax的峰值出现在海拔800—900m,西北坡出现在海拔1800m。东南坡立木密度在海拔1500m处达最高值,而西北坡立木密度变化不明显,仅在海拔1900m以上明显下降。将全部乔木种划分为常绿阔叶、针叶和落叶阔叶等三种生活型,分析不同生活型的生长特征发现,常绿阔叶种类的胸高断面积和(total basal area,TBA)在低海拔占比例大;针叶种类沿海拔出现两个峰值,与分布两种不同针叶林种类有关;落叶阔叶林的TBA在各海拔段均占一定比例,但在西北坡的比例要高于东南坡。两坡三种生活型的TBA沿海拔梯度变化特征基本上相似。     

2000-2017年秦岭山地植被物候变化特征及其南北差异

气候变化背景下开展山地过渡带植被物候变化规律及区域差异研究对于揭示过渡带对气候变化的响应方式具有重要意义。基于2000-2017年MODIS EVI₂数据,反演了秦岭山地植被物候参数并建立了遥感物候数据集,分析了近18年来秦岭山地植被物候变化的时空特征及其南北差异。结果表明：①秦岭山地植被物候变化表现出明显的地形和气候地域分异规律,尤以高海拔区的变化最为显著,全区GSS （物候始期）主要发生于70-130DOY （Day of Year）,83.29%的区域呈提前趋势,提前主要集中在0-5d/10a （44.46%）与5-10d/10a （28.60%）;GSE （物候末期）主要发生于270-310DOY,50.17%的区域呈推迟趋势,变化趋势不明显;GSL （生长期）集中在150-210d,65.34%的区域呈延长趋势,延长在0-5d/10a （19.28%）、5-10d/10a （20.71%）及10-15d/10a （14.12%）均有分布。②秦岭山地GSS对气候变化的响应程度显著大于GSE,南北坡植被物候变化不仅存在区域差异且存在季节差异,GSS北坡较南坡平均约早6.2d且南坡提前趋势较北坡显著,GSE南坡较北坡平均约晚5.8d且北坡推迟趋势较南坡显著,GSL北坡较南坡约长18.7-23.2d。③GSS、GSS及GSS变化表现出显著的海拔敏感性,随着海拔上升,GSS逐渐推迟,GSE逐渐提前,GSL逐渐缩短,三者在海拔≤600m及≥2700m地区随海拔变化的波动幅度较大,南北坡三者随海拔的变化亦存在明显的差异,海拔每上升100m,北坡GSS推迟1.76d,GSE提前0.25d,GSL缩短2.01d;南坡GSS推迟1.50d,GSE提前0.44d,GSL缩短1.94d。④不同植被垂直带上GSS、GSE及GSL的变化存在明显差异,尤以≤600m植被带上及高山灌丛草甸带上的差异最为明显,且三者在高山灌丛草甸带的发生时间及时长北坡与南坡发生转换,表现为GSS、GSE、GSL北坡较南坡分别平均早3.5d、晚2.9d、长6.4d。     

雨雪冰冻灾害对南岭蝴蝶资源的影响

南岭国家级自然保护区巳发现蝴蝶442种,其中不乏有中国分布新纪录和新种。常绿阔叶林中有蝴蝶339种,山地常绿针阔叶林中有蝴蝶369种,山顶常绿阔叶苔藓矮林中有蝴蝶71种;这些蝶类属东洋区的有360种,占总数的81.45%;属古北区的有48种,占总数的10.86%;跨区系分布的有34种,占总数的7.69%;南岭蝶类与福建省蝶类相似百分率高达77.27%,说明两地有共同的起源与演化过程。2008年初的雨雪冰冻灾害使南岭海拨500～1000m森林生态遭受严重破坏,各种蝴蝶在林中的种群密度骤降,海拨700～800m的蝶类仅为海拨1100～1200m冻害较轻林地蝶类数量的23%;整个林区蝶类的种群密度极低,与常年相比,降低率约为90%。凤蝶科的种群在调查地段发现的只占常年见到的37.5%。     

基于立体气候观测的粤北山区热量资源特征

利用粤北山区南岭南北坡面11个自动气象站2009-2011年逐日气温观测资料,统计包括平均气温≥10 ℃初日、平均气温≥15 ℃终日、10~15 ℃持续日数、平均气温≥10 ℃活动积温、最低气温≤5 ℃日数、逐月平均气温等热量因子,并建立了各热量因子与海拔的线性回归模型.结果表明: 研究期间,南岭山区热量因子与海拔呈极显著相关,相同海拔南北坡面的热量资源有着明显差异;随海拔升高,界限温度初日推迟终日提前、界限温度持续日数缩短、活动积温降低、积温日数减少、年平均气温下降;南坡的各热量因子垂直变率均大于北坡.本研究结果可用于拟合无测站地区垂直方向上的热量资源分布,并为农业气候精细区划提供依据.     

温带草原与暖温带落叶阔叶林交错区植被建群种生态位研究——以山西恒山南北坡植被为例

在中国植被分区上,山西恒山是温带草原地带与暖温带落叶阔叶林地带的交错区。本文采用Shannon-Wiener 生态位宽度指数将南北坡群落的建群种群分别划分为3个生态类群。南坡的山蒿、小红菊、披针叶苔草、地榆,北坡的披针叶苔草、山菊、硬质早熟禾、麦瓶草、地榆占据较宽的生态位,生态位泛化比较明显。而南坡的鹅绒委陵菜、三裂叶绣线菊、虎楱子、沙棘,北坡的长芒草、碱茅、山蒿、珠芽蓼、铃铃香、三裂叶绣线菊、沙棘、青杨占据较窄的生态位,这与种群所处的具体生境密切相关。南坡16个建群种群构成的240个种对中有100个种对表现出生态位重叠,占整个种对的41.9%,表明恒山南坡16个种群间具有比较显著的生态位重叠。北坡21个建群种构成的420个种对中69个种对有生态位重叠,占整个种对的16.4%,说明这21个种群并不表现出显著的生态位重叠,各种群间生态位明显分离,说明不同种群利用资源的差异性比较显著。这主要是由于恒山南坡山势平缓,而北坡陡峭,南坡植被呈连续性分布,而北坡植被由于海拔高差大,植被垂直带谱中经常有断带现象,所以,生态位重叠现象比较少见。通过对南北坡建群种群的生态位宽度和生态位重叠的整体比较,可以比较客观的确立恒山作为温带草原地带与暖温带落叶阔叶林地带的分界。     

海南鹦哥岭地区的鱼类物种多样性与分布特点

作者分别于2001年和2005年对海南中部鹦哥岭的鱼类进行了实地调查,记录到62种鱼类,其中23种为鹦哥岭地区新记录种.结合文献资料,该地区共记载有淡水鱼类7目20科59属75种(含亚种),占海南岛已知淡水鱼类的70.8%:海南特有种16个,占海南特有淡水鱼类的80.0%.鱼类群落中以山区溪流性小型鱼类为主.鹦哥岭南北两坡(南坡昌化江流域,北坡南渡江流域)共有的鱼类共36属42种,占鹦哥岭纯淡水鱼类总种数的60.0%.但两坡的鱼类组成存在一定差异:昌化江流域以山区溪流性鱼类为主,南渡江流域则较多平原江河性物种.利用多样性指数,得出鹦哥岭鱼类物种多样性最高的是南渡江流域的南开河和昌化江流域万冲河段的支流.鱼类的垂直分布集中在海拔200-600 m的中低海拔水体,海拔600 m以上鱼类稀少,而在900 m以上没有发现鱼类.有关部门近年已在鹦哥岭建立自然保护区,为有效保护珍贵的鱼类资源,按照当地鱼类水平和垂直分布特点划定鱼类重点保护河段是十分必要的.     

The differences of butterfly (Lepidoptera, Papilionoidea) communities in habitats with various degrees of disturbance and altitudes in tropical forests of Vietnam

A survey was conducted on the species composition, richness and abundance of Papilionoidea (excluding Lycaenidae) butterfly fauna in habitats with various degrees of disturbance and altitudes in tropical forests at Tam Dao National Park, northern Vietnam in 2001. The transect method was used to collect data in the survey. Six transects representing different habitat types at two sites, one site located at a low elevation of 200–250 m a.s.l., and the other located at a high elevation of 950–1000 m a.s.l., were chosen: three transects for each site, with a length of 500 m for each transect. A total of 3594 individuals of 127 species in 240 sets of data were recorded from various habitats. The differences in butterfly composition, species richness, abundance and diversity in different habitat types and altitudes were analyzed. The results showed significant differences of butterfly diversity among the different habitat types and between the low and high altitude sites. The butterfly diversity, species richness and species abundance in the low elevation habitats were higher than in the high elevation habitats. The highest diversity of butterflies occurred in the mixed habitats of agriculture, scrub and clearing lands of high disturbance. However, butterflies most important for conservation are associated with undisturbed or moderately disturbed forests only.     

The structure and spatial organization of the butterfly fauna (Lepidoptera,Rhopalocera) of the Ural Mountains

The butterfly fauna of the Ural Mountains contains 233 species: Papilionidae (6 species), Pieridae (23), Lycaenidae (64), Nymphalidae (60), Satyridae (57), and Hesperiidae (23). The number of butterfly species in seven regional and 29 local faunas generally increases gradually from north to south. The mean number of species in the local butterfly faunas is 127 in the southern Urals and slightly over 50 in the Polar Urals. The arealogical structure of the fauna is determined by the distribution of species recorded in 24 meridional and 19 latitudinal groups which together result in 80 distribution patterns. Based on comparison of the local butterfly faunas of the Urals, two large, historically formed faunistic complexes are distinguished: southern and northern. Either complex contains two faunistic complexes of the second order, hypoarctic and boreal in the former, and southern boreal and subboreal in the latter. The faunas of the Kazakhstan part of the Urals form a separate subboreal semi-arid complex, whereas the extreme boreal fauna of Pay-Khoy forms an independent arctic complex.     

秦岭太白山区蝶类多样性的研究

秦岭太白山北坡蝶类组成共有78种,隶属6个科,43属。其中凤蝶科Papilionidae 3属8种,粉蝶科Pieridne 7属19种,眼蝶科sartyridae 5属9种,蛱蝶科Nymphalidae 15属27种,友蝶科Lycaenidae 7属8种,弄蝶科Hesperiidae 6属7种。新记录3种。     

湖南壶瓶山国家级自然保护区蝶类区系组成及垂直分布的初步研究

2006年对湖南壶瓶山国家级自然保护区的蝶类资源进行了专题调查,共采集到蝴蝶标本1050号,初步鉴定出134种,结合文献资料记载,共记录了153种,隶属于10科85属。蛱蝶科为优势科,计30属(占35.29%)61种(39.87%)。区系成分以东洋界种类为主,计79种(51.63%),广布种60种(39.22%),而古北界种类仅14种(9.15%)。蝶类呈4个垂直带分布,但主要(88.01%)分布于海拔1100 m以下的常绿阔叶林带。多数蝴蝶适应范围比较窄,仅分布于某一垂直带内。在科级水平上,粉蝶科、眼蝶科和蛱蝶科中具多带种较多,是当地广布类群。     

Ecological and faunistic review of butterflies (Lepidoptera,Hesperioidea et Papilionoidea) of Daghestan: Part 1

An ecological and faunistic review of 170 butterfly species from Daghestan based on original data is presented. The distribution and ecological characteristics of species (phenology, voltinism, biotopic distribution, population density and its dynamics, and the cycle of preimaginal stages) are described. The first part of the paper deals with the families Hesperiidae and Lycaenidae. Zoogeographic analysis and ecological characteristics of the regional fauna will be given in the second communication.     

喜马拉雅山哺乳动物物种多样性垂直分布格局

生物多样性的空间分布及其相关机制一直是生态学、生物地理学和保护生物学研究的热点问题。山地生态系统生境异质性和生物多样性高, 适合研究生物多样性空间分布及其相关机制。喜马拉雅山脉位于青藏高原南缘, 是全球生态热点区域。其地形复杂, 海拔落差大(100-8,844 m), 具有明显的垂直气候带。本研究通过整合野外调查和文献资料, 系统地分析了10目23科160属313种喜马拉雅山地区哺乳动物物种多样性的垂直分布格局, 发现该区域哺乳动物总体及其子集的物种多样性垂直分布格局都为左偏倚的中峰格局, 物种多样性在海拔900-1,400 m之间最高, 不同物种子集的物种多样性垂直分布格局的模式有所不同。UPGMA聚类分析表明, 喜马拉雅山地区哺乳动物群落沿海拔梯度可以划分为5个聚类簇(海拔100-1,500 m、1,500-2,000 m、2,000-3,000 m、3,000-4,200 m以及4,200-6,000 m的地区), 大致与该地区植被的垂直带分布相吻合。喜马拉雅山地区哺乳动物物种多样性在中低海拔最为丰富, 可能跟东洋界与古北界生物群扩散后的交汇地带相关。喜马拉雅山区贯通南北的沟谷是生物扩散和迁移的通道, 沟谷内水热资源较好, 气候稳定性高, 为高山生态系统内各种生物创造了栖息条件。综上, 喜马拉雅山沟谷地区是生物多样性热点地区, 也是生物扩散和交流关键的“生态走廊”, 应加强对喜马拉雅山沟谷地区的保护, 以维系该区域较高的生物多样性。     

太白山南坡吸血虻类的垂直分布及区系分析

太白山南坡的吸血虻类有2亚科,5属、46种。分布于8个垂直带,以1000-1500m的松栎林带最多,600-1000m的常绿阔叶林和落叶林混交林带次之, 1500-2000m的杂木林带第三,600m以下,2000m以上较少。 其区系为古北界与东洋界过渡地带,以古北界为主,600-2000m为过渡中心,1000-1500m为两界分界地带。     

Fauna characteristics and ecological distribution of Carnivora and Artiodactyla in Niubeiliang National Nature Reserve,China

Niubeiliang National Nature Reserve (NNR,108°45'-109°04'E,33°47'-33°56'N)is located on the eastern range of the Qinling Mountains in Shannxi Province,China and spans the southern and northern slopes of Mt.Qiuling.A transect survey and investigation were carried out in NNR to determine the fauna characteristics and ecological distribution of carnivora and artiodactyla from May 2003 to August 2004.The NNR has 18 mammals (carnivore and artiodactyl),two of which belong to the first class and seven to the second class of state key protected wildlife in China.The results of this study indicated that ungulates were abundant in the NNR,as all ungulates that were distributed within bit.Qiuling could be found within the reserve.However,only45.5%of the carnivores distributed within Mt.Qinling were detected within the NNR.Among the mammals,there were 12 oriental species (66.7%),1 palearctic specie (5.5%)and 5 widely-distributed species (27.8%).The NNR is a crossing area of palearctic species and oriental species on the zoogeographical regions,and it is a transitional area from the oriental realm to the palearctic realm.The results of the analysis on the ecological distribution of carnivore and artiodactyl in the area showed that their elevation ranges had large differences.The species whose elevation ranges above 1300 m,about 1000 m,and in 450-700 m occupied one third respectively.The results also indicated that species richness for the mammals in the NNR peaked at a middle elevation (rising at first,then descending with the increase in elevation).Not only on the southern slope,but also on the northern slope of Mt.Qinling,the number of species distributed in the area at 1800-2200 m a.s.l.was the largest (more than 80%),while the number of species distributed in the area above 2 600 m a.s.l.was the smallest (about 50%).Elevation gradients of species richness for the mammals in the NNR also embodied the mammal distributions among the vegetation types.The number of species distributed in the mixed coniferous and broadleaf deciduous forest at middle elevations was the largest,while the number of species distributed in the broadleaf deciduous forest at middle and low elevations,subalpine coniferous forest,subalpine shrubbery and meadow was relatively smaller.     

Species richness and trait composition of butterfly assemblages change along an altitudinal gradient

Species richness patterns along altitudinal gradients are well-documented ecological phenomena, yet very little data are available on how environmental filtering processes influence the composition and traits of butterfly assemblages at high altitudes. We have studied the diversity patterns of butterfly species at 34 sites along an altitudinal gradient ranging from 600 to 2,000 m a.s.l. in the National Park Berchtesgaden (Germany) and analysed traits of butterfly assemblages associated with dispersal capacity, reproductive strategies and developmental time from lowlands to highlands, including phylogenetic analyses. We found a linear decline in butterfly species richness along the altitudinal gradient, but the phylogenetic relatedness of the butterfly assemblages did not increase with altitude. Compared to butterfly assemblages at lower altitudes, those at higher altitudes were composed of species with larger wings (on average 9 %) which laid an average of 68 % more eggs. In contrast, egg maturation time in butterfly assemblages decreased by about 22 % along the altitudinal gradient. Further, butterfly assemblages at higher altitudes were increasingly dominated by less widespread species. Based on our abundance data, but not on data in the literature, population density increased with altitude, suggesting a reversed density–distribution relationship, with higher population densities of habitat specialists in harsh environments. In conclusion, our data provide evidence for significant shifts in the composition of butterfly assemblages and for the dominance of different traits along the altitudinal gradient. In our study, these changes were mainly driven by environmental factors, whereas phylogenetic filtering played a minor role along the studied altitudinal range.