不同木本植物功能型当年生小枝功能性状差异

为探讨不同植物功能型之间小枝功能特征的差异,在重庆金佛山和缙云山分别采集20和26个木本植物,选择当年生的小枝测定其叶片和枝条性状。结果表明:1)叶片厚度表现为:落叶植物<常绿植物,乔木<灌木;单叶面积和叶片总面积表现为:落叶植物>常绿植物,乔木>灌木;不同植物功能型间小枝的叶片数量均无显著差异。2)落叶植物和乔木的小枝横截面积、小枝长度和小枝干重均显著高于常绿植物和灌木,不同植物功能型间小枝密度无显著差异。3)与常绿植物和灌木相比,落叶植物和乔木有较高的展叶效率(单位长度小枝支撑的叶片面积),小枝的出叶强度(单位长度小枝支撑的叶片数)无显著差异。4)在小枝水平上,常绿植物比落叶植物投入更多的生物量到叶片。     

上海辰山植物园不同生活型木本植物枝叶大小关系的比较

植物枝叶生长普遍存在显著的正相关关系，决定了植物构型塑造和生物量分配。以上海辰山植物园149种木本植物为对象，通过测定顶枝上70 cm长枝条的直径、叶面积及其生物量，比较相同生境条件下不同生活型木本植物的枝叶大小关系。结果表明，枝条截面积与总叶面积间呈异速生长关系（a=1.148 6，CI=1.000 6~1.302 3），枝条干重与叶干重间呈等速生长关系（a=1.054 2，CI=0.921 3~1.205 6），不同生活型均具有相同的斜率系数a。不同生活型的异速生长常量b（y轴截距）存在显著差异，相同枝条截面积下落叶乔木比常绿乔木和常绿灌木具有更大的叶面积，相同枝条干重下常绿乔木和落叶乔木比常绿灌木具有更大的叶干重。这可能与不同生活型木本植物水分竞争效率和叶建成成本差异有关。     

桂林岩溶石山青冈群落主要木本植物功能性状变异与关联

研究植物功能性状变异以及不同性状之间的关系, 有助于了解植物对环境的适应策略, 对揭示群落构建和生物多样性维持机制具有重要意义。本研究以桂林岩溶石山青冈群落18种主要木本植物为研究对象, 采用单因素方差分析、混合线性模型以及Pearson相关分析和主成分分析等方法探讨了不同生长型和生活型物种的9个枝、叶功能性状(叶绿素含量、叶片厚度、叶面积、叶干质量、比叶面积、叶干物质含量、叶组织密度、小枝干物质含量和小枝组织密度)的变异与关联。结果表明: (1) 9个功能性状的变异程度不同, 叶面积和叶干质量的种内和种间变异系数最大, 小枝干物质含量和小枝组织密度的种内和种间变异系数最小。(2)在生长型水平上, 乔木、灌木和木质藤本的绝大部分功能性状差异显著。(3)对于不同生活型植物, 除叶面积和比叶面积为落叶植物显著大于常绿植物外, 其余7个功能性状皆为常绿植物显著大于落叶植物。(4)不同生长型和生活型植物功能性状的种内和种间变异大小存在差异, 除部分植物功能性状在一些功能型上表现为种内变异高于种间变异, 其余功能性状的种间变异皆高于种内变异。(5)各功能性状之间关系在个体水平和物种水平大致相同, 但是个体水平上的显著相关比例高于物种水平。研究发现, 植物功能性状的种间变异基本高于种内变异, 但种内变异不容忽略。此外, 不同生长型和生活型物种采取不同的生态策略来适应喀斯特生境。今后的研究应基于个体水平采样并结合环境因子从生长型和生活型等不同功能型角度上深入探究植物功能性状在种内和种间等不同尺度上的变异与关联。     

Variation and correlation in functional traits of main woody plants in the Cyclobalanopsis glauca community in the karst hills of Guilin,southwest China

研究植物功能性状变异以及不同性状之间的关系, 有助于了解植物对环境的适应策略, 对揭示群落构建和生物多样性维持机制具有重要意义。本研究以桂林岩溶石山青冈群落18种主要木本植物为研究对象, 采用单因素方差分析、混合线性模型以及Pearson相关分析和主成分分析等方法探讨了不同生长型和生活型物种的9个枝、叶功能性状(叶绿素含量、叶片厚度、叶面积、叶干质量、比叶面积、叶干物质含量、叶组织密度、小枝干物质含量和小枝组织密度)的变异与关联。结果表明: (1) 9个功能性状的变异程度不同, 叶面积和叶干质量的种内和种间变异系数最大, 小枝干物质含量和小枝组织密度的种内和种间变异系数最小。(2)在生长型水平上, 乔木、灌木和木质藤本的绝大部分功能性状差异显著。(3)对于不同生活型植物, 除叶面积和比叶面积为落叶植物显著大于常绿植物外, 其余7个功能性状皆为常绿植物显著大于落叶植物。(4)不同生长型和生活型植物功能性状的种内和种间变异大小存在差异, 除部分植物功能性状在一些功能型上表现为种内变异高于种间变异, 其余功能性状的种间变异皆高于种内变异。(5)各功能性状之间关系在个体水平和物种水平大致相同, 但是个体水平上的显著相关比例高于物种水平。研究发现, 植物功能性状的种间变异基本高于种内变异, 但种内变异不容忽略。此外, 不同生长型和生活型物种采取不同的生态策略来适应喀斯特生境。今后的研究应基于个体水平采样并结合环境因子从生长型和生活型等不同功能型角度上深入探究植物功能性状在种内和种间等不同尺度上的变异与关联。     

武夷山常绿阔叶林木本植物小枝生物量分配

小枝是木本植物的重要组成单元,研究其生物量分配策略有利于了解不同物种对环境的响应。本文以武夷山常绿阔叶林群落中19种木本植物的小枝为研究对象,采取标准化主轴回归(standardized major axis,SMA)的方法分析小枝的叶重、叶片面积、叶柄重、茎重、叶数量等性状特征,研究在群落水平上和不同生活型上,常绿阔叶林群落木本植物的小枝生物量分配格局。结果表明:群落水平上小枝重、总叶重和茎重三者间均呈等速生长关系。同样的,在乔木和灌木不同生活型分类中,茎重和总叶重也呈等速生长关系。但是,小枝重和总叶重、茎重之间的关系却不一致:小枝重和总叶重在乔木、灌木中分别呈等速生长关系和异速生长关系;小枝重和茎重在乔木、灌木中分别呈异速生长关系和等速生长关系;此外,单叶重和出叶强度在群落水平上呈负等速生长关系。然而,这种负等速生长关系并不存在于不同生活型的植物中。小枝水平上,总叶柄重和小枝重、总叶重均呈小于1的异速生长关系,即随叶的增大,小枝需要分配更多生物量用于运输组织和支撑结构(叶柄)的构建。因此,叶柄投资是限制亚热带常绿阔叶林当年生枝和叶增大的重要因素,对于小枝和叶大小的优化选择具有重要影响。     

浙江天童常绿阔叶林12种常绿木本植物的落叶格局

落叶格局反映了植物叶片适应环境的生理生态策略,是植物功能群的重要特征。本研究通过跟踪观测枝条上老叶(一年生及以上)和当年生小枝新叶整年的数量动态,揭示了天童地区12种常见常绿阔叶木本植物不同的落叶格局,并且发现同一群落层次内有多种类型存在。根据落叶特性可分为季节性集中落叶型和全年持续性落叶型,其中4个物种表现为春季集中落叶型,2个物种为夏季集中落叶型,1个物种为秋季集中落叶型,1个物种为春秋季集中落叶型,4个物种为全年持续性落叶型;研究还发现阳性物种(包括冠层乔木及林窗下灌木)多为集中落叶型,而耐阴灌木物种多为全年持续性落叶型,并且阳性物种相比于耐阴灌木物种年总落叶比例更大,表明叶片更新率更快。结合当年气候数据及出叶物候,本文讨论了新叶生长、台风干扰及水分等因素对落叶格局的影响。通过对亚热带常绿阔叶林植物落叶格局及其影响因素的研究有望能进一步探索植物对环境的适应策略。     

浙江天童木本植物Corner法则的检验:个体密度的影响

Corner法则反映了植物枝叶大小和数量配置的构型策略,但是,对于个体密度如何影响枝叶关系的理解仍不够深入。该研究选择浙江天童的25个植物群落,通过比较枝大小(横截面积)-叶大小(总叶面积)关系和枝大小(横截面积)-枝数量(分梢密度)关系,分析个体竞争对植物Corner法则的影响。结果显示:1)在不同密度区间,枝横截面积和总叶面积均显著异速正相关。2)个体水平上,枝大小-叶大小回归方程的截距在低密度区间显著小于高密度区间,表明在枝大小一定的条件下,高密度群落的植物当年生枝条会支撑更大的总叶面积;而物种水平上,枝大小-叶大小回归方程的截距在不同密度区间没有显著性差异。3)枝横截面积与分梢密度显著负相关,且各密度区间也存在显著小于–1的共斜率。4)个体水平和物种水平的分析结果都显示,枝横截面积与分梢密度回归方程的截距在不同密度区间无显著差异,表明高密度植物并没有比低密度植物在单位大小枝条上配置更多的分枝。总之,植物枝大小-叶大小关系和枝大小-枝数量关系各自在不同的密度区间具有共同的变化斜率,反映了天童地区植物Corner法则不随个体密度变化而改变。但是,枝叶关系回归方程截距的改变表明,个体竞争的加大会使得植物在枝叶大小的配置策略上进行调整,从而可能通过生态位分化促进物种共存。     

不同生活型绿化植物叶片碳同位素组成的季节特征

通过测定北京地区不同生活型绿化植物叶片的碳同位素组成(δ13C值),从植物种和生活型两个方面研究植物水分利用效率的自然可变性。结果表明:所测定的75种植物(隶属于35科65属)的叶片的δ13C值变幅,春季为-30.7‰--23.4‰,夏季为-31.5‰--25.1‰,秋季为-31.4‰--23.9‰;落叶灌木种间差异不显著(p=0.114),而常绿乔木(p=0.005)、落叶乔木(p0.001)、常绿灌木(p=0.022)、草本植物(p0.001)和藤本植物(p=0.001)的种间差异显著或极显著;同一生活型植物叶片的δ13C季节差异显著,春季叶片的δ13C值显著大于夏秋两季(常绿乔木除外),不同生活型植物叶片的δ13C值在春、夏、秋3个季节差异都达到了极显著水平(春季p=0.001、夏季p0.001、秋季p0.001),且叶片的δ13C值表现出乔木树种灌木树种藤本植物草本植物、常绿植物落叶植物的规律。因此,植物种和生活型均会引起植物叶片δ13C值的变化,但δ13C受生活型变化的影响较大,表明不同生活型植物的水分利用效率具有明显差异。     

浙江天童木本植物Corner法则的检验:微地形的影响

枝叶的大小和数量关系表征了植物应对环境胁迫的水力结构特征,当前,对其在微生境间的变化规律不太清楚。该研究在浙江天童常绿阔叶林中,按照地形的凸凹差异,各选择了10个群落,采用标准化主轴估计方法,分别比较了植物枝大小(横截面积)-叶大小(总叶面积)关系、枝大小(横截面积)-枝数量(枝稠密度)关系和叶大小(单叶面积)-叶数量(生叶强度)关系在两类生境的变化。结果发现:1)在两类生境中,枝横截面积和总叶面积显著异速正相关(p0.001),存在显著大于1的共斜率;其回归方程截距在凹型生境显著大于凸型生境,表明在一定枝大小下,凹型生境比凸型生境的植物枝条支撑更大的叶面积;2)枝横截面积与枝稠密度显著负相关(p0.001),且在两生境间存在显著小于–1的共斜率;回归方程截距在生境间无显著差异(p0.05),表明凹型与凸型生境的植物在单位大小枝条配置的分枝数相同;3)单叶面积与生叶强度显著负相关(p0.001),且也在生境间存在显著小于–1的共斜率;回归方程的截距在凹型生境显著大于凸型生境,表明在叶片大小相同时,凹型比凸型生境的植物在单位大小枝条上支撑的叶片数更多。综上,与凸型生境相比,凹型生境植物单位大小枝条更倾向于支持数量较多的大叶片。本研究证明,植物Corner法则和叶大小-叶数量的权衡在局域尺度也具普适性。枝叶大小和叶数量配置的调整体现了植物水力结构对凸凹生境不同水分供应的选择偏好。     

亚热带常绿林不同冠层小枝叶面积-叶生物量关系研究

叶面积与叶生物量的关系对于理解植物叶片的碳收益和投资权衡策略具有重要意义。收益递减假说认为植物的叶面积与叶生物量成显著异速生长关系，其异速生长指数<1.0，但该假说是否适用于不同生活型（常绿与落叶）亚热带木本植物不同冠层高度（上下冠层）当年生小枝的叶片仍不清楚。以江西亚热带常绿阔叶林的69种常绿与落叶木本植物当年生小枝上的叶为研究对象，采用标准化主轴回归估计（standardized major axis estimation，SMA）方法检验不同冠层高度和生活型叶面积与叶生物量的异速生长关系。结果显示：（1）当年生小枝叶生物量在不同冠层高度和生活型的植物中无显著差异（P>0.05），叶面积在常绿和落叶植物中有显著差异（P<0.05），常绿和落叶植物的比叶重存在显著差异（P<0.05），而落叶植物的比叶重在不同冠层高度存在显著差异（P<0.05），同一冠层，常绿植物比叶重显著高于落叶植物（P<0.05）；（2）69种植物的叶面积与叶生物量异速生长指数具有物种特异性，60.9%的物种叶面积与叶生物量呈等速生长关系；（3）不同冠层和生活型植物的叶面积与叶生物量呈等速生长关系，但其异速生长常数在不同冠层高度与生活型间存在差异。这些结果表明冠层高度和生活型未改变叶面积-生物量之间的等速生长关系，不支持"收益递减"假说。     

Testing of Corner’s rules across woody plants in Tiantong region,Zhejiang Province: effects of individual density

Aims Corner’s rules reflect the architectural strategies of plants with respect to deployment of twig size and leaf size, as well as of the number of twigs and leaves. The objective of this study was to examine how Corner’s rules would vary among plants with different individual densities.
Methods The study site is located in the Tiantong National Forest Park (29.87° N, 121.65° E), Zhejiang Province. We measured twig cross-sectional area (twig size), total leaf area (leaf size per twig), and the number of twigs at a given twig size (branching intensity) in woody plants across 25 plots differing in stem density to examine the effects of individual competition on Corner’s rules. The standardized major axis (SMA) analysis was conducted to determine the quantitative relationships of twig size with leaf size and branching intensity.
Important findings Significant, positive allometric relationships between cross-sectional area and total leaf area were found in individual plants across all communities. There was no significant difference among communities of different density intervals in the slope of the linear regression between cross-sectional area and total leaf area of individual plants, and the common slope of the regressions was significantly greater than 1 (p < 0.001). The intercept was significantly greater for plants in communities with higher density than in those with lower density (p < 0.001), indicating that plants in a high density community support greater total leaf area than in a low density community for a given twig size. In contrast, a significant, negative allometric scaling relationship was found between branching intensity and cross-sectional area in individual plants across different communities. Also, nosignificant difference was found among plants in communities of different density intervals in the slope of the regression between branching intensity and cross-sectional area, and the common slope of the regressions was significantly less than –1 (p < 0.001). The intercept for the regression relationship between twig area and branching intensity was the same among plants in communities of different density intervals (p > 0.05), suggesting that plants in a high density community do not deploy more twigs per twig size than in a low density community. In summary, this study demonstrated that plants responded to changes in individual density by maintaining an invariant regression slope for the twig size-leaf size relationship and the twig size-branching intensity relationship, and that the Corner’s rules were not affected by individual density of the communities in the Tiantong region. However, changes in the intercept of the regression between twig size and leaf size indicate that deployment strategies between twig and leaf sizes could be adjusted with increasing individual plant competition, thus structuring species coexistence through niche differentiation.     

我国温带山地森林48种常见树种叶片重量-出叶强度的关系

叶片是植物的主要光合器官, 其质量与数量的权衡关系体现植物对环境的适应策略。在全球气候变化的背景下, 研究叶片质量与数量关系有助于理解植物对环境变化的响应趋势。该研究应用标准化主轴回归方法, 探讨了我国温带山地森林中48个常见树种的单叶干重与出叶强度的权衡关系。结果表明, 所有物种以及落叶阔叶林、常绿和落叶阔叶树种、单叶以及亚冠层阔叶树种的单叶干重与出叶强度表现为异速生长关系; 针叶林、针阔混交林、常绿及落叶针叶树种、复叶以及冠层阔叶树种则表现为等速生长关系。研究结果表明, 叶大小和出叶强度并无恒定的权衡关系。     

Testing of corner’s rules across woody plants in Tiantong region,Zhejiang Province: effects of micro-topography

Aims The size and quantity relationships between twigs and leaves can be used to describe the hydraulic properties of plants in response to environmental stresses. The objective of this study was to examine how twig-leaf relationship would vary with changes in micro-habitat conditions.
Methods The study site is located in the Tiantong National Forest Park (29.87° N, 121.65° E), Zhejiang Province. We measured twig cross-sectional area (twig size), sub-twig cross-sectional area (sub-twig size), individual leaf area, total leaf area (leaf size per twig), the number of twigs at a given twig size (twig intensity), and the number of leaves at a given twig size (leafing intensity) across individual woody plants on 10 plots in each of the convex and concave habitats within an evergreen broad-leaved forest. The standardized major axis (SMA) analysis was conducted to determine the scaling relationships between twig size and leaf size, between sub-twig size and twig intensity, and between leaf size and leafing intensity.
Important findings Significant, positive allometric relationships between twig cross-sectional area and total leaf area were found in plants in both types of micro-habitats (p < 0.001). There was no significant difference between the two micro-habitats in the slope of the regression between twig cross-sectional area and total leaf area, and the common slope of the regressions was significantly greater than 1 (p < 0.001). The intercept was significantlygreater in plants of the concave habitat than in plants of the convex habitat (p < 0.001), indicating that plants in a concave habitat support greater total leaf area at a given twig size than in a convex habitat. Significant, negative allometric scaling relationships were found between twig size and twig intensity in plants in both micro-habitats. There was also no significant difference between the two habitats in the slope of the regression between twig size and twig intensity, and the common slope of the regressions was significantly less than –1 (p < 0.001). The similar intercept in the regression relationship of twig area and twig intensity between the two habitats suggests that plants deploy similar amount of sub-twigs per twig size in both types of habitat. In addition, significant, negative allometric scaling relationships between leaf size and leafing intensity were found to be consistently conserved across micro-habitat types, with the common slope being smaller than –1. A higher value of y-intercept in the scaling relationships of leaf area vs. leafing intensity for plants in the concave habitat indicates that at a given leaf area, more leaves were supported by plants in a concave habitat than in a convex habitat. Overall, plants in a concave habitat tend to deploy more large leaves per twig size than those in a convex habitat. This study demonstrated that both the Corner’s rules and the leaf size-number trade-offs could be generalized to apply at the small local spatial scales. The magnitude and quantitative adjustment of twig-leaf deployment manifests a selection preference of hydraulic properties of plants in coping with changes in water availability between concave and convex habitats.     

Effect of stem length to stem slender ratio of current-year twigs on the leaf display efficiency in evergreen and deciduous broadleaved trees

Aims Branches and leaves are the two main structural units of tree crown composition. Among the adaptive strategies of plants, the functional traits of branches and the relationships between branch traits and leaf traits determine the capacity of trees to access light and space. In this study, our objective is to test the hypothesis that leaf display efficiency is affected by the stem length to stem slender ratio within current-year twigs.Methods The stem length to stem slender ratios of current-year twigs were used as the proxy of stem structure traits. Leaf area ratio (total leaf area per stem mass), leaf density (leaf number per stem length) and leaf/stem mass ratio (total leaf mass per stem mass) were used as the proxies of leaf display efficiency. The relationship between stem structure traits and leaf display efficiency within current-year twigs were studied for 25 evergreen and 60 deciduous broadleaved woody species in Qingliang Mountain, Zhejiang, China. The standardized major axis estimation method was used to examine the scaling relationship between stem structural traits and leaf display efficiency within current-year twigs.Important findings The proxies of leaf display efficiency, measured by leaf area ratio, leaf density or leaf/stem mass ratio, were all significantly and negative correlated with stem length to stem slender ratio within current-year twigs in both evergreen and deciduous broadleaved woody species. This suggested that leaf display efficiency decreased with stem length to stem slender ratios within current-year twigs, which may reflect the role of mechanical safety and light within twigs. The slope of the relationship between leaf display efficiency and stem long-dimension structure traits in evergreen species was not significantly different from the one in deciduous species. In contrast, the y-intercept of the relationship between leaf density and stem long-dimension structure traits was significantly larger in evergreen species than in deciduous species, i.e. the leafing intensity of evergreen species was higher than that of deciduous species. Individual leaf area and specific leaf area were smaller in evergreen species than in deciduous species, which resulted in deciduous species have a larger leaf area per stem mass and leaf mass per stem mass at a given stem length to stem slender ratio compared to evergreen species. It may reflect the conservative adaptive strategy of high consumption and slow benefit in evergreen species. Our results demonstrated that leaf display efficiency could be affected by stem length, and would change with leaf life-span (deciduous versus evergreen).     

清凉峰不同海拔木本植物小枝内叶大小-数量权衡关系

权衡关系是生活史对策理论的基础, 叶大小-数量的权衡关系对理解叶大小进化具有重要的意义。该研究以单叶面积和单叶片干重表示叶大小, 用小枝干重和小枝茎干重表示小枝大小, 采用标准化主轴估计(standardized major axis estimation, SMA)和系统独立比较分析(phylogenetically independent contrast analysis, PIC)的方法, 对浙江省清凉峰自然保护区3个不同海拔落叶阔叶木本植物当年生小枝内的叶大小与数量间的关系进行研究。结果显示, 无论叶大小和小枝大小是用面积或干重表示, 在每个海拔, 叶大小与出叶强度均存在显著的等速负相关关系, 表明在落叶阔叶木本植物中发现的叶大小与出叶强度之间的权衡关系在不同生境物种中是普遍存在的, 植物在叶大小方面的种间变化, 可能不是自然选择的直接产物, 而是叶片数量变化权衡关系的一个副产物。不同海拔间的比较显示, 高海拔物种的叶面积或干重与出叶强度相关关系的y轴截距比中、低海拔物种小, 表明在出叶强度一定的情况下, 高海拔物种比低海拔物种具有更小的叶大小。与高海拔物种相比, 中海拔物种的共同斜率沿共同主轴有一个向上的位移, 表明中海拔物种比高海拔物种具有更大的叶大小, 但出叶强度更小。这些结果表明生境对叶大小-数量的权衡关系具有显著的影响, 中海拔生境具有更适宜植物生长的气候及养分条件, 而高海拔的低温等不利影响使得叶片变小。     

浙江天童国家森林公园5种常绿阔叶植物的一次和二次抽枝进程

中国东部亚热带常绿阔叶林中, 部分常绿木本物种具有明显的二次抽枝现象, 即在春天完成第一次抽枝, 间隔一定的时间后又开始新一轮抽枝。但是关于这些植物第二次抽枝的进程, 迄今鲜有报道, 限制了人们对这些植物生活史对策的理解。该文以浙江天童常绿阔叶林中有二次抽枝的5种植物光叶山矾(Symplocos lancifolia)、檵木(Loropetalum chinense)、窄基红褐柃(Eurya rubiginosa var. attenuata)、杨梅(Myrica rubra)和栲树(Castanopsis fargesii)为研究对象, 调查并比较了第一次抽枝和第二次抽枝在昆虫取食压力、展叶动态和小枝投资大小3个方面的差异, 探讨第二次抽枝动态的主要特点。结果表明: 1)昆虫取食压力上, 杨梅、栲树2种植物第二次抽枝的叶片虫食率显著高于第一次抽枝, 光叶山矾、檵木和窄基红褐柃3种植物第一、二次抽枝的叶片虫食率没有差异; 2)在现叶速率(叶片数量的增加速率)上, 同一物种第一、二次抽枝的叶片数量增长模式相同, 光叶山矾、檵木、窄基红褐柃和杨梅4个物种呈持续式增长, 栲树则呈爆发式增长, 但是完成现叶所需时间并不完全相同, 光叶山矾、窄基红褐柃和杨梅第二次抽枝完成现叶比第一次少6-9天, 檵木和栲树第一、二次抽枝完成现叶所需时间则无差异; 3)在展叶速率上, 光叶山矾、檵木和窄基红褐柃第二次抽枝显著高于第一次抽枝, 但第一次抽枝较晚的杨梅和栲树第一、二次抽枝之间没有差异; 4)调查的5种植物, 第二次抽枝的投资总量均小于第一次抽枝, 光叶山矾、窄基红褐柃、杨梅和栲树4种植物, 第二次抽枝形成的小枝在叶片数量、单叶面积、小枝长度和小枝直径上都显著小于第一次抽枝, 檵木第二次抽枝形成的小枝在叶片数量和小枝长度上没有差异, 单叶面积和小枝直径则显著小于第一次抽枝。总体上看, 所研究物种第二次抽枝中的叶片虫食率、现叶速率和展叶速率都不小于第一次抽枝, 而第二次抽枝小枝投资总量较小, 这些可能是物种对相对较大的昆虫取食压力和即将来临的冬天不利条件等的适应。     

浙江天童常绿阔叶林不同演替阶段木本植物的水力结构特征

水力结构是植物应对环境形成的与水分运输相关的形态策略.探索不同演替阶段和群落不同高度层植物的水力结构特征, 有助于理解植物的水分运输和利用策略.该研究以浙江天童常绿阔叶林演替前中后期群落的上层木(占据林冠层的树种)和下层木(灌木层物种)为对象, 测定了演替共有种(至少存在于两个演替阶段的物种)和更替种(仅存在于某一演替阶段的物种)的枝边材比导率,叶比导率和胡伯尔值, 以及边材疏导面积,末端枝总叶面积和枝条水势, 分析植物水力结构在群落上层木和下层木间以及在演替阶段间的差异, 及其与枝叶性状的相关关系.结果显示: (1)上层木植物边材比导率和叶比导率显著高于下层木植物(p < 0.05); (2)上层木和下层木的边材比导率与叶比导率在演替阶段间均无显著差异(p > 0.05); 上层木的胡伯尔值在演替阶段间无显著差异, 下层木的胡伯尔值随演替显著下降(p < 0.05); (3)上层木共有种仅边材比导率随演替进行显著降低(p < 0.05), 更替种的3个水力结构参数在演替阶段间无显著差异; 下层木共有种水力结构参数在演替阶段间无明显差异, 更替种仅胡伯尔值随演替减小(p < 0.05); (4)植物边材比导率与枝疏导面积和末端枝所支撑的总叶面积显著正相关(p < 0.01), 胡伯尔值与枝条水势及末端枝总叶面积显著负相关(p < 0.01).以上结果表明: 天童常绿阔叶林演替各阶段上层木比下层木具有更大的输水能力和效率; 随着演替进行, 上层木与下层木的共有种和更替种边材比导率的相反变化表明上层木水力结构的变化可能由微生境变化引起, 而下层木水力结构特征的变化可能由物种更替造成.     

亚热带常绿阔叶林植物叶小枝的异速生长

 植物生态学研究的重要内容之一是识别和定量刻画种间生态变异的主要维数,叶大小小枝大小维（谱）是其中之一,目前的研究相对比较薄弱,两者之间是异速还是等速生长关系仍存在着争论。亚热带常绿阔叶林植物叶大小-枝大小维的研究报道很少。该文以我国东部亚热带典型区域福建梅花山常绿阔叶林的68种常绿乔灌木植物为对象,进行了叶-小枝关系及其生态意义的研究。结果表明：1）小枝茎截面积与叶干重、总叶面积和单叶面积之间的SMA斜率分别为1.29、1.23和1.18,呈现异速生长关系,支持叶大小 小枝大小为异速生长的相关研究结论,但SMA斜率低于预期值,其原因及生态意义有待进一步研究;2）小枝总叶面积与单叶面积呈显著正相关,而与叶片数量不相关,反映了小枝总叶面积的增加主要是由单叶面积大小决定的,可能与这一地区湿润气候有关;而单叶面积与枝条长度呈正相关则可能反映了植物对常绿阔叶林内较弱光照环境的适应;3）叶干重同小枝干重、叶面积为等速生长关系,可能反映了植物与动物之间代谢方式的差异。     

Hydraulic architecture of evergreen broad-leaved woody plants at different successional stages in Tiantong National Forest Park,Zhejiang Province,China

Aims Hydraulic architecture is a morphological strategy in plants to transport water in coping with environmental conditions. Change of hydraulic architecture for plants occupying different canopy layers within community and for the same plant at different successional stages reflect existence and adaptation in plant's water transportation strategies. The objective of this study was to examine how hydraulic architecture varies with canopy layers within a community and with forest succession.Methods The study site is located in Tiantong National Forest Park, Zhejiang Province, China. Hydraulic architectural traits studied include sapwood-specific hydraulic conductivity, leaf-specific hydraulic conductivity, Huber value, sapwood channel area of twigs, total leaf area per terminal twig, and water potential of twigs. We measured those traits for species that occur in multiple successional stages (we called it "overlapping species") and for species that occur only in one successional stage (we called it "turnover species") along a successional series of evergreen broadleaved forests. For a given species, we sampled both overstory and understory trees. Hydraulic architectural traits between overstory and understory trees in the same community and at successional stages were compared. Pearson correlation was used to exam the relationship between hydraulic architectural traits and the twig/leaf traits.Important findings Sapwood-specific hydraulic conductivities and leaf-specific hydraulic conductivities were significantly higher in overstory trees than those in understory trees, but did not significantly differ from successional stages. Huber value decreased significantly for understory trees, but did not change for overstory trees through forest successional stages. For overstory trees, a trend of decreasing sapwood-specific hydraulic conductivity was observed for overlapping species but not for turnover species with successional stages. In contrast, for understory trees, a trend of decreasing Huber values was observed for turner species but not for overlapping species with successional stages. Across tree species, sapwood-specific hydraulic conductivity was positively correlated with sapwood channel area and total leaf area per terminal twig size. Huber value was negatively correlated to water potential of twigs and total leaf area per terminal twig size. These results suggest that water transportation capacity and efficiency are higher in overstory trees than in understory trees across successional stages in evergreen broadleaved forests in Tiantong region. The contrasting trends of sapwood-specific hydraulic conductivity between overlapping species and turnover species indicate that shift of microenvironment conditions might lead to changes of hydraulic architecture in overstory trees, whereas species replacement might result in changes of hydraulic architecture in understory trees.     

The effects of leaf size,leaf habit,and leaf form on leaf/stem relationships in plant twigs of temperate woody species

Question: Do thick‐twigged/large‐leaf species have an advantage in leaf display over their counterparts, and what are the effects of leaf habit and leaf form on the leaf‐stem relationship in plant twigs of temperature broadleaf woody species? Location: Gongga Mountain, southwest China. Methods: (1) We investigated stem cross‐sectional area and stem mass, leaf area and leaf/lamina mass of plant twigs (terminal branches of current‐year shoots) of 89 species belonging to 55 genera in 31 families. (2) Data were analyzed to determine leaf‐stem scaling relationships using both the Model type II regression method and the phylogenetically independent comparative (PIC) method. Results: (1) Significant, positive allometric relationships were found between twig cross‐sectional area and total leaf area supported by the twig, and between the cross‐sectional area and individual leaf area, suggesting that species with large leaves and thick twigs could support a disproportionately greater leaf area for a given twig cross‐sectional area. (2) However, the scaling relationships between twig stem mass and total leaf area and between stem mass and total lamina mass were approximately isometric, which indicates that the efficiency of deploying leaf area and lamina mass was independent of leaf size and twig size. The results of PIC were consistent with these correlations. (3) The evergreen species were usually smaller in total leaf area for a given twig stem investment in terms of both cross‐sectional area and stem mass, compared to deciduous species. Leaf mass per area (LMA) was negatively associated with the stem efficiency in deploying leaf area. (4) Compound leaf species could usually support a larger leaf area for a given twig stem mass and were usually larger in both leaf size and twig size than simple leaf species. Conclusions: Generally, thick‐twigged/large‐leaf species do not have an advantage over their counterparts in deploying photosynthetic compartments for a given twig stem investment. Leaf habit and leaf form types can modify leaf‐stem scaling relationships, possibly because of contrasting leaf properties. The leaf size‐twig size spectrum is related to the LMA‐leaf life span dimension of plant life history strategies.