森林生态系统细根周转规律及影响因素

根系周转是陆地生态系统碳循环的关键过程,对研究土壤碳库变化及全球气候变化均具有重要意义。然而由于根系周转率的测量计算方法较多,不同方法得出的结果差异较大,且目前对全球区域尺度上森林生态系统根系周转的研究还不够充分,使得全球森林生态系统根系周转变化规律仍不清楚。该研究通过收集文献数据并统一周转率计算方法,对全球5种森林类型的细根周转空间格局进行整合,同时结合土壤理化性质和气候数据,得出影响森林生态系统细根周转的因子。结果表明,不同森林类型细根周转率存在显著差异,且随着纬度的升高逐渐降低;森林生态系统细根周转率与年平均温度和年平均降水量呈正相关;森林生态系统细根周转率与土壤有机碳含量呈正相关但与土壤pH值呈负相关。该研究为揭示森林生态系统细根周转规律及机制提供了科学依据。     

森林生态系统细根周转规律及影响因素

根系周转是陆地生态系统碳循环的关键过程, 对研究土壤碳库变化及全球气候变化均具有重要意义。然而由于根系周转率的测量计算方法较多, 不同方法得出的结果差异较大, 且目前对全球区域尺度上森林生态系统根系周转的研究还不够充分, 使得全球森林生态系统根系周转变化规律仍不清楚。该研究通过收集文献数据并统一周转率计算方法, 对全球5种森林类型的细根周转空间格局进行整合, 同时结合土壤理化性质和气候数据, 得出影响森林生态系统细根周转的因子。结果表明, 不同森林类型细根周转率存在显著差异, 且随着纬度的升高逐渐降低; 森林生态系统细根周转率与年平均温度和年平均降水量呈正相关; 森林生态系统细根周转率与土壤有机碳含量呈正相关但与土壤pH值呈负相关。该研究为揭示森林生态系统细根周转规律及机制提供了科学依据。     

林木细根寿命及其影响因子研究进展

 细根周转要消耗大量的C,它影响森林生态系统C分配格局与过程和养分循环,对生态系统生产力具有重要意义。细根的周转取决于细根的寿命,细根寿命越短,周转越快,根系对C的消耗也越多。大量研究表明,细根的寿命与地上部分C向根系供应的多少有密切关系,同时也与细根直径大小、土壤中N和水分的有效性、土壤温度以及根际周围的土壤动物和微生物的活动有关。本文综述了国外近年来在该领域里的研究进展,特别是对控制细根寿命的机理和主要影响因子进行了评述,目的是引起国内研究者的关注,促进我国根系生态学的研究与发展。     

森林细根分解研究进展

细根分解是森林生态系统养分和能量循环的重要环节,是一个贯穿着淋溶粉碎等物理作用以及土壤生物参与的生物化学作用交织在一起的复杂过程,对深入揭示陆地生态系统地表C平衡,认识细根分解的影响因素和机理具有重要意义.但由于细根埋藏于地下,难以在不破坏原有的土壤环境的情况下进行取样,同时分解过程对气候变化的响应受到土壤层的缓冲,致使各种因素对细根分解相对重要性的不同,是细根分解格局和地上部分凋落物分解格局差异的主要原因.本文综述了细根分解的影响因素及研究方法,提出了细根分解未来研究方向,以期加强细根分解的系统研究.     

森林生态系统根系生物量研究进展

在森林生态系统功能过程研究中,特别是在生产力和生物地化学循环方面,根系的作用不容忽视,但是,由于研究方法和研究者的观念等方面的限制,对于根系的研究还远不及地上部分受到重视。而关于细根生物量,周转率和生产力等方面的是很少有人问津。为推动我国根系生物学研究的发展,本一面地介绍了９种典型的测度细根生物量的方法。包括：收获法、钻土芯法、内生长土芯法、平衡法、根观测实验室法、土壤碳平衡法、挖土块法、间接法和     

Root exudates and their ecological consequences in forest ecosystems: Problems and perspective

植物根际过程与调控机理研究已成为当前土壤学最活跃、最敏感的研究领域, 而根系分泌物作为根系-土壤-微生物界面物质能量交换和信息传递的重要媒介物质, 是构成根际微生态系统活力与功能特征的内在驱动因素, 是根际概念与根际过程存在的重要前提和基础。然而, 由于传统的根际过程研究更强调以实际生产问题为导向, 加之农作物生长周期较短、操作便利等诸多因素, 以往对植物根系分泌物研究主要聚焦在农业生态系统, 而有关根系分泌物在森林生态系统中的重要作用与调控机理研究甚少, 认识相对零散和片段化。基于此, 该文结合作者实际研究工作中的主要成果和该领域国际前沿动态, 综述了森林根系分泌物的生态重要性, 重点论述了目前森林根系分泌物生态学研究中存在的主要问题与不足, 在此基础上展望了未来森林根系分泌物生态学研究中值得关注的重点方向和研究内容。     

森林根系分泌物生态学研究:问题与展望

植物根际过程与调控机理研究已成为当前土壤学最活跃、最敏感的研究领域,而根系分泌物作为根系-土壤-微生物界面物质能量交换和信息传递的重要媒介物质,是构成根际微生态系统活力与功能特征的内在驱动因素,是根际概念与根际过程存在的重要前提和基础。然而,由于传统的根际过程研究更强调以实际生产问题为导向,加之农作物生长周期较短、操作便利等诸多因素,以往对植物根系分泌物研究主要聚焦在农业生态系统,而有关根系分泌物在森林生态系统中的重要作用与调控机理研究甚少,认识相对零散和片段化。基于此,该文结合作者实际研究工作中的主要成果和该领域国际前沿动态,综述了森林根系分泌物的生态重要性,重点论述了目前森林根系分泌物生态学研究中存在的主要问题与不足,在此基础上展望了未来森林根系分泌物生态学研究中值得关注的重点方向和研究内容。     

养分输入方式对森林生态系统土壤养分循环的影响研究进展

土壤养分循环对森林生态系统稳定性维持、树种选择及更新、可持续经营具有重要意义,掌握养分输入来源及过程可指导森林生态系统物质循环与能量流动分析及生态功能评估。凋落物、根系周转、根系分泌物是森林土壤养分的主要来源,是土壤养分循环的重要组成部分。本文分析了3种主要养分输入方式及其影响因素,总结了凋落物组成及理化性质、生物因子、环境因子等对凋落物分解及土壤养分循环的影响;综述了细根底物性质、树种组成、土壤生物、环境因子变化对细根周转及土壤养分循环的影响;探讨了根系分泌物对土壤养分循环过程的作用,基于此,提出了该领域亟需深入研究的重要方向,以期为相关研究及森林生态系统养分管理提供参考。     

中国温带、亚热带和热带森林45个常见树种细根直径变异

 细根在发挥植物功能以及生态系统碳和养分循环过程中起着重要作用。为了解我国不同森林生态系统细根直径变化规律, 提供建立根系模型的基础, 该文研究了我国温带、亚热带和热带45个常见树种1～5级根直径的变异以及直径与根序的关系。结果表明: 1)在所有树种中, 1级根直径最细, 5级根直径最粗, 直径随根序的增加而增加。此外, 同一根序的直径在不同树种间变异较大, 在不同生态系统中, 各树种1级根的总体平均直径呈现温带<亚热带<热带的格局。2)不同生态系统树种同一根序平均直径变异程度不同, 各个根序都是温带最小, 亚热带次之, 热带最大。3)细根内部各个根序的平均直径变异的52%由根序解释, 33%由树种解释, 生态系统类型和生活型分别解释7%和2%。不同系统不同树种直径的变异说明无法用统一的直径级来研究根的功能, 也无法用统一的根序和直径间的关系来建立根系形态模型。今后的研究需要进一步认识根序和直径在不同树种中如何与根的功能相联系。     

鼎湖山9种常见树木细根组织N浓度的季节变化

根系在植物养分吸收、生理代谢和生态系统过程中发挥着重要作用, 然而我们对根系结构与功能的了解十分有限。以往对根系的研究往往用直径大小定义细根, 忽略了细根系统内部结构和功能的异质性。近年来的研究表明, 细根系统中的根级(root order)与根的功能有较好的相关性, 低级根个体多属于短命的吸收根。温带森林的研究表明, 非木质化的吸收根在氮(N)浓度上呈现显著的季节变化, 而与木质化的结构性根缺少N浓度的季节变化形成鲜明对比。该研究通过研究亚热带树木不同根级N浓度的季节变化, 试图验证假说: 木本植物中, 非木质化的根中N浓度具有明显的季节变化是一个普遍现象。通过对鼎湖山常见的9种木本植物不同根级的研究, 证实了在1年内的6个采样时段, 各根级的N浓度之间都存在显著差异; 与温带树种不同, 各树种不同根级的N浓度变化呈现不同的季节格局, 这与假说不符。因此认为温带与亚热带森林生态系统之间的环境差异以及树种之间的差异是导致亚热带树种低级根的N浓度季节变化不显著, 而三、四级根变化相对显著的主要原因。这些发现对于认识树木根系统内及个体水平的N分配与利用格局具有重要的意义。     

Decomposition and nutrient release of grass and tree fine roots along an environmental gradient in southern Patagonia

Decomposition of fine roots is a fundamental ecosystem process that relates to carbon (C) and nutrient cycling in terrestrial ecosystems. However, this important ecosystem process has been hardly studied in Patagonian ecosystems. The aim of this work was to study root decomposition and nutrient release from fine roots of grasses and trees (Nothofagus antarctica) across a range of Patagonian ecosystems that included steppe, primary forest and silvopastoral forests. After 2.2 years of decomposition in the field all roots retained 70–90% of their original mass, and decomposition rates were 0.09 and 0.15 year^?1 for grass roots in steppe and primary forest, respectively. For N. antarctica roots, no significant differences were found in rates of decay between primary and silvopastoral forests (k = 0.07 year^?1). Possibly low temperatures of these southern sites restricted decomposition by microorganisms. Nutrient release differed between sites and root types. Across all ecosystem categories, nitrogen (N) retention in decomposing biomass followed the order: tree roots > roots of forest grasses > roots of steppe grasses. Phosphorus (P) was retained in grass roots in forest plots but was released during decomposition of tree and steppe grass roots. Calcium (Ca) dynamics also was different between root types, since trees showed retention during the initial phase, whereas grass roots showed a slow and consistent Ca release during decomposition. Potassium (K) was the only nutrient that was rapidly released from both grass and tree roots in both grasslands and woodlands. We found that silvopastoral use of N. antarctica forests does not affect grass or tree root decomposition and/or nutrient release, since no significant differences were found for any nutrient according to ecosystem type. Information about tree and grass root decomposition found in this work could be useful to understand C and nutrient cycling in these southern ecosystems, which are characterized by extreme climatic conditions.     

Can ectomycorrhizal colonization of Pinus resinosa roots affect their decomposition?

In many forest ecosystems, fine root litter comprises a large pool of organic carbon and nutrients. In temperate climates ectomycorrhizal fungi colonize the roots of many forest plant species. If ectomycorrhizal colonization influenced root decomposition, it could significantly influence carbon sequestration and nutrient cycling. Fungal tissues and fine roots may decompose at different rates and, therefore, ectomycorrhizal colonization may either hasten or retard root decomposition. Unfortunately, no comparisons of the decomposition of roots and ectomycorrhizal fungi have yet been made. Therefore, we compared decomposition of Pinus resinosa fine roots and ectomycorrhizal fungi from a Pinus resinosa plantation. We also compared the decomposition rates of nonmycorrhizal Pinus resinosa fine roots with roots colonized by nine species of ectomycorrhizal fungi. We found that the several tested isolates of ectomycorrhizal fungi decomposed far more rapidly than the fine roots and that ectomycorrhizal colonization either had no significant effect on root decomposition or significantly increased root decomposition depending on the isolate of fungus. We conclude that the composition of an ectomycorrhizal fungal community may affect carbon and nutrient cycling through its influence on root decomposition.     

Divergent responses of fine root decomposition to removal of understory plants and overstory trees in subtropical Eucalyptus urophylla plantations

Plant and Soil - Plant fine roots play an important role in forest nutrient cycling. However, how fine root decomposition responds to plant removal is poorly understood. We aimed to examine the...     

树木根系碳分配格局及其影响因子

根系作为树木提供养分和水分的“源”和消耗C的“汇”,在陆地生态系统C平衡研究中具有重要的理论意义。尽管20多年来的研究已经认识到根系消耗净初级生产力占总净初级生产力较大的比例,但是,根系（尤其是细根）消耗C的机理以及C分配的去向一直没有研究清楚。主要原因是细根消耗光合产物的生理生态过程相当复杂,准确估计各个组分消耗的C具有很大的不确定性,常常受树种和环境空间和时间异质性、以及研究方法的限制。综述了分配到地下的C主要去向,即细根生产和周转、呼吸及养分吸收与同化、分泌有机物、土壤植食动物,及有关林木地下碳分配机理的几种假说,分析了地下碳分配估计中存在的不确定性。目的是在全球变化C循环研究中对生态系统地下部分根系消耗的C以及分配格局引起重视。     

应用微根管法测定细根指标方法评述

树木细根(直径<2mm)在森林生态系统能量流动和物质循环中起着重要的作用。原有的细根生产周转研究中常采用的土钻法、内生长法、挖掘法、根室法和土柱法等,均不能直接观察到细根的动态变化。微根管法是一种非破坏性、可定点直接观察和研究植物根系的方法,为研究细根的生长、衰老、死亡、分解和再生长的过程提供了有效的工具,尤其适用于细根周转、寿命和分解等方面的研究。但该技术不能直接测定单位面积的细根生物量、细根化学组成及细根周转对土壤碳和养分循环的影响,需要与土钻法结合。本文就运用微根管法对细根生物量、生产、周转和寿命等指标的研究方法进行了评述。     

Importance of short-lived components of a dry tropical forest for biomass production and nutrient cycling

Abstract. Short-lived components in a dry tropical forest ecosystem in India - tree foliage, fine roots and herbaceous plants - are shown to be important for biomass production and nutrient cycling. With 62 % they contribute much more to the dry matter production than the long-lived components- tree boles, branches and coarse roots - which make up only 38 %. The contribution of short-lived components to the total uptake of different nutrients was also high: 18 - 30 % for tree foliage, 26 - 34 % for fine roots and 6–19 % for herbs; their share in the total nutrient storage is less: 6–19 % for tree foliage, 4–8 % for fine roots and 0.6–1.3 % for herbs. The transfer of nutrients by the short-lived components was also substantial: 31 - 46 % for foliage, 7–24% for herbs and 33–45% for fine roots. The results indicate that the short-lived components play a significant role in the functioning of a dry tropical forest.     

Seasonal patterns of fine root demography in a cool-temperate deciduous forest in central Japan

In forest ecosystems, fine roots have a considerable role in carbon cycling. To investigate the seasonal pattern of fine root demography, we observed the fine root production and decomposition processes using a minirhizotron system in a Betula-dominated forest with understory evergreen dwarf bamboo. The length density of fine roots decreased with increasing soil depth. The seasonal patterns of each fine root demographic parameter (length density of visible roots, rates of stand-total fine root production and decomposition) were almost the same at different soil depths. The peak seasons of the fine root demographic parameters were observed in the order: stand-total fine root production rate (late summer) > length density of the visible roots (early autumn) > stand-total fine root decomposition rate (autumn, and a second small peak in spring). The fine root production rate was high in the latter part of the plant growing season. Fine root production peaked in late summer and remained high until the end of the tree defoliation season. The higher stand-total fine root production rate in autumn suggests the effect of understory evergreen bamboo on the stand-total fine root demography. The stand-total fine root decomposition rate was high in late autumn. In the snow-cover period, the rates of both fine root production and decomposition were low. The fine root demographic parameters appeared to show seasonal patterns. The fine root production rate had a clearer seasonality than the fine root decomposition rate. The seasonal pattern of stand-total fine root production rate could be explained by both overstory and understory above-ground productivities.     

Aboveground Tree Growth Varies with Belowground Carbon Allocation in a Tropical Rainforest Environment

Young secondary forests and plantations in the moist tropics often have rapid rates of biomass accumulation and thus sequester large amounts of carbon. Here, we compare results from mature forest and nearby 15–20 year old tree plantations in lowland Costa Rica to evaluate differences in allocation of carbon to aboveground production and root systems. We found that the tree plantations, which had fully developed, closed canopies, allocated more carbon belowground - to their root systems - than did mature forest. This increase in belowground carbon allocation correlated significantly with aboveground tree growth but not with canopy production (i.e., leaf fall or fine litter production). In contrast, there were no correlations between canopy production and either tree growth or belowground carbon allocation. Enhanced allocation of carbon to root systems can enhance plant nutrient uptake, providing nutrients beyond those required for the production of short-lived tissues such as leaves and fine roots, and thus enabling biomass accumulation. Our analyses support this deduction at our site, showing that enhanced allocation of carbon to root systems can be an important mechanism promoting biomass accumulation during forest growth in the moist tropics. Identifying factors that control when, where and for how long this occurs would help us to improve models of forest growth and nutrient cycling, and to ascertain the role that young forests play in mitigating increased atmospheric carbon dioxide.     

中国温带和亚热带8个树种叶和吸收根协同分解

叶和细根(2mm)是森林生态系统的分解主体,二者是否协同分解,将极大影响所属植物在生态系统碳(C)循环中的物种效应。已有研究显示,叶和细根的分解关系具有极大的不确定性,认为很大程度上归因于细根内部具有高度的异质性,导致叶和细根在功能上不相似。为此,使用末梢1级根和细根根枝作为研究对象,它们在功能上同叶类似,称为吸收根。通过分解包法,分别在黑龙江帽儿山和广东鹤山,研究了2个阔叶树种和2个针叶树种(共8个树种)的叶和吸收根持续2a多的分解。结果发现,分解速率k(a~(-1),负指数模型)在8个树种整体分析时具有正相关关系(P0.05),在相同气候带或植物生活型水平上是否相关,受叶的分解环境及吸收根类型的影响;N剩余量整体上并不相关,亚热带树种的叶和细根根枝的N剩余量在分解1a后高度显著正相关,温带树种的叶和1级根的N剩余量在分解2a后显著高度正相关。本研究中,根-叶分解过程是否受控于相同或相关的凋落物性质是决定根-叶分解是否相关的重要原因,其中分解速率与酸溶组分正相关、与酸不溶组分负相关。比较已有研究,总结发现,根-叶分解关系受物种影响较大,暗示气候变化导致物种组成的改变将极大影响地上-地下关系,也因此影响生态系统C循环。