灌木年轮学研究进展

灌木往往分布在树线以上或以北的高海拔和高纬度地区以及干旱、半干旱区,是把传统上以乔木为主的树轮研究扩展至森林分布界限以外的唯一选择.尽管灌木具有以上研究潜力,迄今用于树木年代学研究的灌木种类仅有30种左右.介绍了灌木年轮研究方法,综述了过去几十年来环北极高纬度地区,干旱、半干旱区以及高海拔地区的灌木年轮研究的主要进展.主要研究进展如下:(1)发掘一些灌木的树木年代学潜力;(2)揭示限制灌木生长的主要环境因子,并尝试利用灌木年轮宽度等指标重建过去区域气候变化历史;(3)探讨全球变暖的背景下,灌木的生长或分布范围的变化;(4)通过人为控制增温来揭示变暖对灌木生理特征和生长的影响.这些研究展示了灌木在扩展传统乔木树轮研究网络方面的潜力,也是树木年代学研究中最有前景的研究方向之一.目前的灌木年轮学研究多集中于环北极苔原带.作为地球的第三极,青藏高原具有广泛的高山灌木分布,具有把青藏高原边缘区以乔木为主的树木年轮网络扩展至更高海拔和高原内部的潜力.青藏高原高山灌木的年轮学研究并没有引起足够的重视.青藏高原高山灌木的生长是如何适应极端环境条件的,全球变暖的背景下,青藏高原高山灌木的分布和生长正在发生哪些变化等,都有待深入研究.     

树木年轮对气候变化的响应研究及其应用

树木年轮的宽度、密度、亮度和同位素含量等都与气候因子光、温和湿度等的变化有复杂的相关关系, 对这种相关生理机理的研究也有较大的进展。综述了这方面的研究进展及这些成果在古气候和环境研究、生理生态学、林学、群落学甚至历史社会学等领域的应用。     

树木年轮宽度与气候变化关系研究进展

 树木的生长和立地环境密切相关并受多种气候因子的影响。树木年轮宽度的增加与温度、降水、太阳辐射、CO2浓度等气候因子有着复杂的相关关系。在干旱或半干旱地区,温度是限制树木生长的重要气候因子。生长季开始时最低温度的升高有利于延长生长季,与年轮宽度正相关;但是当生长季温度过高时,即使降水非常充裕,当年也只能形成窄年轮。生长季的温度过高则会加快土壤蒸发失水量并提高蒸汽压差,使土壤水分不足而不利于树木生长,因而生长季的高温多表现为与年轮宽度的负相关。生长期内降水量与树木的径向生长也成正相关,但当生长季的降水量充足或过多时,降水对树木径向生长不相关或负相关。受温度和降水共同调控的土壤湿度是树木径向生长的主要限制因子,良好的水分状况对树木生长起决定性作用。某一地区的太阳辐射能量高常会导致高温少雨,故高强度的太阳辐射使表土的湿度降低而不利于树木的径向生长。而在受季风影响的地区,树木年轮宽度的增加与当年雨季的气候变化关系不大。当年季风到来之前的气候（温度和降水）是树木生长的主要限制因子。有关CO2浓度的升高对树木生长的影响,研究的结果很不一致。一些温室实验及田间控制实验证明,CO2浓度的升高能对短命的一年生草本植物和植物幼苗产生“施肥效应”,并有利于其生长;还有些研究证明CO2浓度的升高能使高海拔地带的树木年轮宽度增加;但也有些研究认为CO2浓度的升高对生长在自然条件下的自然植被影响不大。近年来,有关树木径向生长和气候变化的研究越来越引起人们的关注,相关研究也取得了较大的进展。这些研究在帮助人们了解和研究古气候变化对森林植被的影响,以及预测未来全球变化对陆地生态系统的影响等方面有重要的理论和现实意义。综述了气候变化对树木年轮宽度影响的研究进展和应用,并概述了研究方法和发展前景,希望能加快和拓宽这一领域的发展。     

陕北沙地3种典型灌木根木质部解剖结构及水力特性

比较了陕北沙地沙柳、柠条和沙棘3种典型灌木不同土壤深度(0～20和30～50 cm)根木质部解剖结构和水力特性.结果表明： 沙柳具有较高的叶水势,根木质部导管平均最大直径(d_max)、平均最小直径(d_min)、平均导管面积(A_lum)以及导管面积占木质部面积比例(A_ves/A_xyl)显著高于柠条和沙棘,根导管密度(VD)与沙棘相当但显著高于柠条;沙柳根的比导水率分别为柠条和沙棘的5.0和2.8倍;沙柳根栓塞脆弱性指数与柠条根相当,但显著高于沙棘根.表明沙柳属耗水型水分利用策略,而柠条和沙棘属节水型水分利用策略,且柠条更耐旱.3种灌木在2个土层深度的d_max、d_min和A_lum无显著差异,但30～50 cm土层根VD和A_ves/A_xyl显著高于表层;30～50 cm土层根比导水率显著高于表层根,但脆弱性指数小于表层根,深层根具有高的水分传输效率和低的水力脆弱性.     

呼伦贝尔沙地樟子松年轮生长对气候变化的响应

以内蒙古呼伦贝尔地区沙地樟子松为样本,建立了樟子松树木年轮宽度年表,应用相关分析和响应函数分析等年轮气候学方法,研究了樟子松径向生长对气候变化的响应。结果表明,樟子松年轮宽度与4月和6—9月平均温度呈显著负相关关系(P<0.05);与各月降水量多呈正相关关系,特别是与当年5—8月的月降水量呈显著正相关关系(P<0.05);树轮年表与前一年10月至当年10月的PDSI均呈显著正相关关系(P<0.05),其中与5月份PDSI的相关性最高。响应函数分析表明,年表与当年6—7月的平均气温、上一年10月和当年5—7月份的降雨存在显著的相关性,与5—7月份PDSI存在较显著的正相关性;综合来看,呼伦贝尔沙地樟子松生长同时受降水和温度的影响,其径向生长与气候因子间的关系属于降水敏感型,为区域降水重建提供了科学基础。     

多枝柽柳年轮生长速率测量及TRGR指标优势分析

灌木对生境和气候变化具有高度敏感性,其年轮资料在认识区域环境演变过程、全球气候变化和环境保护中具有重要作用。灌木植株在生长过程中受遗传和极端环境的影响,年轮常出现偏心和不规则生长,这使得专业年轮分析软件测量的年轮宽度数据难以准确反映其整体径向生长信息。为探讨适合于寒旱区灌木年轮学研究的年轮测量指标和测量方法,研究以该区域荒漠常见植物多枝柽柳(Tamarix ramosissima Ledeb.)为研究对象,通过U-net深度学习方法,获得年轮提取训练模型,自动获取扫描轮盘各年早材区域。轮盘扫描及语义分割后的图像经GIS配准赋坐标、ENVI图像处理后,借助GIS编辑和测量工具,完成多枝柽柳各年年轮生长速率(Tree-ring growth rate, TRGR)、年轮宽度(Tree-ring width, TRW)和树木基部断面积生长增量(Basal area increment, BAI)的测量;研究基于Timesat Savitzky-Golay(S-G)滤波时间序列拟合,获取点样尺度归一化植被指数(Normalized difference vegetation index, ND...     

河北木兰围场油松年轮生态学的初步研究

运用树木年轮气候学方法,研究了河北木兰围场油松的生长与气候要素之间的关系.结果表明：油松生长对环境变化十分敏感,以早材最为敏感.5、6月气温与油松生长存在显著的负相关关系;6月的降水和相对湿度对油松早材的生长有促进作用, 上年9月到翌年9月的降水对油松生长有更强的促进作用;12月到翌年3月的相对湿度对油松晚材生长的促进作用较干旱和全轮显著;油松的生长与大尺度气候波动存在一定的相关性.1951—2006年间,围场地区增温明显.随气温的升高,油松生长对温度和降水的敏感性下降,且有向相反方向转变的趋势.百年尺度上5—6月平均气温的重建值与观测值差异较大,说明当地油松的宽度生长对气候因子变化的敏感性波动较大.     

长白山北坡落叶松年轮年表及其与气候变化的关系

运用相关函数及单年分析等树木年轮气候学方法,研究了长白山北坡落叶松径向生长与气候变化的关系.结果表明,落叶松的生长对环境变化相当敏感,温度是影响其生长的主要因子.但不同海拔的落叶松对温度的响应明显不同.高海拔分布的落叶松只与当年6月的温度指标显著相关,而低海拔的落叶松与环境的关系相对复杂,除当年的4、5月外,上一年的6、9月温度以及上年9月的湿润指数都显著影响其生长.这说明不同环境梯度上的同一树种对气候变化的响应不尽相同.     

腾格里沙漠人工植被区固沙灌木影响深层土壤水分的动态模拟研究

灌木是我国沙漠地区主要的优势植物类型,固沙灌木的存在有益于沙丘的固定进而有利于退化沙漠生态系统的生态恢复。基于腾格里沙漠沙坡头地区50多年的人工植被区长期观测研究,建立生态-水文模型模拟了该地区固沙灌木盖度和深层土壤水分的动态变化过程,结果表明,固沙灌木的建立改变了沙区原有的生态-水文过程,在固沙灌木建立40多年后,固沙灌木的盖度和深层土壤水分达到了新的平衡状态。灌木盖度逐渐稳定在(10±0.9)%左右,而深层土壤水分稳定在(2.58±0.2)%左右。因此,在年均降雨量为186mm的腾格里沙漠沙坡头地区,土壤水分的最大植被承载力为:灌木和生物土壤结皮的盖度分别维持在10%和60%,深层土壤水分维持在3%左右。     

长白山北坡落叶松年轮年表及其与气候变化的关系

运用相关函数及单年分析等树木年轮气候学方法,研究了长白山北坡落叶松径向生长与气候变化的关系.结果表明,落叶松的生长对环境变化相当敏感,温度是影响其生长的主要因子.但不同海拔的落叶松对温度的响应明显不同.高海拔分布的落叶松只与当年6月的温度指标显著相关,而低海拔的落叶松与环境的关系相对复杂,除当年的4、5月外,上一年的6、9月温度以及上年9月的湿润指数都显著影响其生长.这说明不同环境梯度上的同一树种对气候变化的响应不尽相同.     

Arctic shrub growth trajectories differ across soil moisture levels

The circumpolar expansion of woody deciduous shrubs in arctic tundra alters key ecosystem properties including carbon balance and hydrology. However, landscape‐scale patterns and drivers of shrub expansion remain poorly understood, inhibiting accurate incorporation of shrub effects into climate models. Here, we use dendroecology to elucidate the role of soil moisture in modifying the relationship between climate and growth for a dominant deciduous shrub, Salix pulchra, on the North Slope of Alaska, USA. We improve upon previous modeling approaches by using ecological theory to guide model selection for the relationship between climate and shrub growth. Finally, we present novel dendroecology‐based estimates of shrub biomass change under a future climate regime, made possible by recently developed shrub allometry models. We find that S. pulchra growth has responded positively to mean June temperature over the past 2.5 decades at both a dry upland tundra site and an adjacent mesic riparian site. For the upland site, including a negative second‐order term in the climate–growth model significantly improved explanatory power, matching theoretical predictions of diminishing growth returns to increasing temperature. A first‐order linear model fit best at the riparian site, indicating consistent growth increases in response to sustained warming, possibly due to lack of temperature‐induced moisture limitation in mesic habitats. These contrasting results indicate that S. pulchra in mesic habitats may respond positively to a wider range of temperature increase than S. pulchra in dry habitats. Lastly, we estimate that a 2°C increase in current mean June temperature will yield a 19% increase in aboveground S. pulchra biomass at the upland site and a 36% increase at the riparian site. Our method of biomass estimation provides an important link toward incorporating dendroecology data into coupled vegetation and climate models.     

植物物候与气候研究进展

植物物候及其变化是多个环境因子综合影响的结果,其中气候是最重要、最活跃的环境因子。主要从气候环境角度分析了植物物候与气候以及气候变化间的相互关系,概述了国内外有关植物物候及物候模拟等方面的研究进展。表明,温度是影响物候变化最重要的因子;同时,水分成为胁迫因子时对物候的影响也十分重要。近50a左右,世界范围内的植物物候呈现出了春季物候提前,秋季物候推迟或略有推迟的特征,从而导致了多数植物生长季节的延长,并成为全球物候变化的趋势。全球气候变暖改变了植物开始和结束生长的日期,其中冬季、春季气温的升高使植物的春季物候提前是植物生长季延长的主要原因。目前对物候学的研究方向主要集中在探讨物候与气候变化之间的关系,而模型模拟是定量研究气候变化与植物物候之间关系的重要方式,国内外已经开发出多种物候模型来分析气候驱动与物候响应之间的因果关系。另外遥感资料的应用也为物候模型研究提供了新的方向。物候机理研究、物候与气候关系以及物候模型研究将是研究的重点。     

Tree ring anatomy indices of Pinus tabuliformis revealed the shifted dominant climate factor influencing potential hydraulic function in western Qinling Mountains

Trees can adjust xylem anatomical structure related with potential hydraulic functions to cope with climate variability. We therefore need a better understanding of how climate variability constrains wood anatomy and tree radial growth. Pinus tabuliformis dominates natural forests and plantations over the western Qinling Mountains, which is one of the ecologically vulnerable areas in China. Here, we investigated the response of P. tabuliformis tree-ring anatomical structure to climate variability by applying wood anatomy analysis, and evaluated the influences of anatomical traits on potential hydraulic functions and the climate significance of intra-annual density fluctuations (IADFs). We found that with the increasing temperature from spring to summer, the negative effect of temperature on the formation and enlargement of earlywood and transition-wood tracheids was gradually enhanced. However, spring precipitation not only had a direct and positive influence on the formation of earlywood, but also had a delaying impact on the transition-wood cell enlargement. Besides, the smaller earlywood tracheid size of P. tabuliformis could be a substantially characteristic reflecting spring drought. The contribution of lumen diameter on conduit wall reinforcement was dominated in earlywood, while the contribution of cell wall thickness was greater than that of lumen diameter in latewood. The different contributions of anatomical traits on conduit wall reinforcement would further affect the response of potential hydraulic function to climate. IADFs of P. tabuliformis could be a potential indicator to reflect the abnormal summer precipitation events in the western Qinling Mountains. IADFs with strong and weak intensity indicated years with high and low rates of change in mid-summer precipitation, respectively. Future warmer and drier climate in the western Qinling Mountains will likely result in the production of smaller tracheids to ensure hydraulic safety, which means the stronger drought resistant of P. tabuliformis in the future. In this study, we linked the xylem anatomy and potential hydraulics functions with intra-seasonal climate variability in the context of climate warming and drying, and proposed some xylem anatomical indices reflecting potential drought events.     

Across climates and species,higher vapour pressure deficit is associated with wider vessels for plants of the same height

While plant height is the main driver of variation in mean vessel diameter at the stem base (VD) across angiosperms, climate, specifically temperature, does play an explanatory role, with vessels being wider with warmer temperature for plants of the same height. Using a comparative approach sampling 537 species of angiosperms across 19 communities, we rejected selection favouring freezing-induced embolism resistance as being able to account for wider vessels for a given height in warmer climates. Instead, we give reason to suspect that higher vapour pressure deficit (VPD) accounts for the positive scaling of height-standardized VD (and potential xylem conductance) with temperature. Selection likely favours conductive systems that are able to meet the higher transpirational demand of warmer climates, which have higher VPD, resulting in wider vessels for a given height. At the same time, wider vessels are likely more vulnerable to dysfunction. With future climates likely to experience ever greater extremes of VPD, future forests could be increasingly vulnerable.     

高山林线与气候变化关系研究进展

20世纪全球气候经历了异常的变化。20世纪是过去1000年中增暖最大的1个世纪,并且90年代是最暖的10年。作为两个生态系统的过渡地带,生态过渡带是监测全球变化的重要地点,而森林和苔原之间的高山林线是全球变化最为敏感的地点。从高山林线树木个体对气候变化的响应、气候变化下林线处树木的更新、林线格局变化以及高山林线与气候变化关系研究中所采用的研究方法等方面,综合论述了国内外的研究进展,最后提出了高山林线研究中需要注意的问题,并对今后的研究趋势作了展望。     

Current and future distribution of the deciduous shrub Hydrangea macrophylla in China estimated by MaxEnt

Climate change has a significant impact on the growth and distribution of vegetation worldwide. Hydrangea macrophylla is widely distributed and considered a model species for studying the distribution and responses of shrub plants under climate change. These results can inform decision‐making regarding shrub plant protection, management, and introduction of germplasm resources, and are of great importance for formulating ecological countermeasures to climate change in the future. We used the maximum entropy model to predict the change, scope expansion/reduction, centroid movement, and dominant climate factors that restrict the growth and distribution of H. macrophylla in China under current and future climate change scenarios. It was found that both precipitation and temperature affect the distribution of suitable habitat for H. macrophylla. Akaike information criterion (AICc) was used to select the feature combination (FC) and the regularization multiplier (RM). After the establishment of the optimal model (FC = QP, RM = 0.5), the complexity and over‐fitting degree of the model were low (delta AICc = 0, omission rate = 0.026, difference between training and testing area under the curve values = 0.0009), indicating that it had high accuracy in predicting the potential geographical distribution of H. macrophylla (area under the curve = 0.979). Overall, from the current period to future, the potential suitable habitat of this species in China expanded to the north. The greenhouse effect caused by an increase in CO₂ emissions would not only increase the area of high‐suitability habitat in Central China, but also expand the area of total suitable habitat in the north. Under the maximum greenhouse gas emission scenario (RCP8.5), the migration distance of the centroid was the longest (e.g., By 2070s, the centroids of total and highly suitable areas have shifted 186.15 km and 89.84 km, respectively).     

灌丛资源及其管理利用研究进展

灌丛是中国山地和干旱地区的常见植被类型,分布范围广泛、生态功能多样、经济价值可观。然而,自然资源、生态环境、国民经济等相关部门多将灌丛拆分归属于森林或草原,其重要性未能充分体现。学术界有关灌丛资源的概念、内涵未有明确统一共识,基于资源属性特点的灌丛资源分区分类体系尚未建立。草原灌丛化的发生范围、速度及其生态影响不够明确,严重影响灌丛资源的高效保护、科学管理与可持续利用。这已然成为亟需凝聚共识和深入探究的理论技术难点与实践问题。建议在科学界定灌丛资源的概念内涵、建立健全灌丛资源分类体系基础上,深入发展和应用灌丛植被多基遥感和人工智能识别技术,科学掌握不同区域灌丛变化特别是草原灌丛化的过程及原因,全面系统地评估灌丛化的生态经济影响,优化分区分类灌丛管理利用策略,促进灌丛资源可持续管理和利用。     

安徽黄山华中五味子次生木质部的生态解剖

对安徽黄山海拔420～1840m的华中五味子茎的次生木质部进行了生态解剖学研究。结果表明,茎的次生木质部为散孔材,导管分子长741.7～1025.2μm,直径为152.4～191.9μm;导管频率60.6～70.2mm-2。纤维管胞长925.2～1046.3μm;木射线类型为异形ⅡA和ⅡB,单列射线高682.1～778.4μm,多列射线高度为1093～1208μm,多列射线宽63.6～92.6μm,射线频率9.2～12.8mm-1。次生木质部解剖特征随异质生境而表现出一定的可塑性,其中,多列射线宽、射线频率、导管分子长度、导管直径等性状的可塑性较大。多重回归分析表明,水分和温度是影响华中五味子次生木质部解剖特征的主导因子。随着空气相对湿度的增加,导管分子长度和直径均增大,射线频率减小。随着降雨量的增加,纤维长度增加。随着最冷月温度的增加,导管频率增加,多列射线宽度减小。随着年较差的增加,单列射线和多列射线高度均减小。     

Enhanced shrub growth in the Arctic increases habitat connectivity for browsing herbivores

Habitat connectivity is a key factor influencing species range dynamics. Rapid warming in the Arctic is leading to widespread heterogeneous shrub expansion, but impacts of these habitat changes on range dynamics for large herbivores are not well understood. We use the climate–shrub–moose system of northern Alaska as a case study to examine how shrub habitat will respond to predicted future warming, and how these changes may impact habitat connectivity and the distribution of moose (Alces alces). We used a 19 year moose location dataset, a 568 km transect of field shrub sampling, and forecasted warming scenarios with regional downscaling to map current and projected shrub habitat for moose on the North Slope of Alaska. The tall‐shrub habitat for moose exhibited a dendritic spatial configuration correlated with river corridor networks and mean July temperature. Warming scenarios predict that moose habitat will more than double by 2099. Forecasted warming is predicted to increase the spatial cohesion of the habitat network that diminishes effects of fragmentation, which improves overall habitat quality and likely expands the range of moose. These findings demonstrate how climate change may increase habitat connectivity and alter the distributions of shrub herbivores in the Arctic, including creation of novel communities and ecosystems.     

暖温带乔木和灌木物候变化及对气候变化的响应

根据2003-2014年气象数据和暖温带3种乔木(辽东栎、五角枫和核桃楸)和3种灌木(土庄绣线菊、毛叶丁香和六道木)的物候观测数据资料, 采用气候倾向率和回归分析等方法, 观察乔木和灌木物候变化特征的差异, 分析温度、降水以及乔木、灌木的物候变化趋势, 同时对气象因子与乔木和灌木物候期的相关关系进行研究。结果表明: ①研究期间, 北京东灵山平均气温呈不显著的上升趋势, 气候倾向率为0.200℃·10a–1, 春季(3–5月)和夏季(6-8月)温度显著上升; 降水量呈下降趋势, 平均减少71.630 mm·10a–1, 总体呈暖、干的趋势。②3种乔木的生长季长度都缩短, 辽东栎、五角枫和核桃楸平均生长季长度分别缩短50.70 d·10 a–1、29.83 d·10a–1和22.36 d·10a–1。3种灌木的生长季长度也都缩短, 土庄绣线菊、毛叶丁香和六道木的平均生长季长度分别缩短42.55 d·10a–1、42.76 d·10a–1和38.15 d·10a–1。乔木和灌木的物候变化趋势相同, 整体表现为春季物候推迟, 秋季物候提前, 生长季长度都缩短且生长季长度相差不大。乔木和灌木都表现出芽期推迟最明显, 每10年推迟达19天以上。③乔木和灌木各物候期与气温总体表现为负相关, 即气温升高, 物候期提前, 其相关性显示出夏季(6-8月)温度对植被物候期影响较大, 夏季温度与各物候期表现为正相关, 即夏季温度升高, 物候期推迟。同时乔木和灌木与总体降水没有明显的相关关系, 但秋季物候与不同时段降水表现不同的相关性, 由此可知夏季温度变化对木本植物春季物候(出芽期、展叶期和首花期)的影响更大, 而秋季物候(叶变色期和落叶期)受温度和降水共同影响。