干旱胁迫对高山柳和沙棘幼苗光合生理特征的影响

为了解干旱河谷-山地森林交错带植物光合生理特征对干旱胁迫的响应。以交错带两种典型植物高山柳(Salix paraqplesia)和沙棘(Hippophae rhamnoides)为研究对象,研究其在不同程度的干旱胁迫条件下植株气体交换参数的日变化特征。干旱胁迫显著降低了两种植物叶片数、叶面积、叶片生物量、比叶面积、色素含量、净光合速率(Pn)、气孔导度(gs)和气孔限制值(Ls)等与光合生理过程密切相关的叶片指标,但增大了胞间CO₂浓度(Ci)和内禀水分利用效率(WUEi)。植物叶片的气体交换参数(如:Pn和gs)日变化并未完全随着光合有效辐射的增强和温度的升高而增加,全天以11:00最大,"午休"现象明显。相对而言,沙棘在干旱胁迫条件下表现出相对较高的叶面积、Pn、gs和WUEi,具有相对更强的适应干旱环境的能力,而高山柳对干旱胁迫更为敏感。     

干旱胁迫对高山柳和沙棘幼苗光合生理特征的影响

为了解干旱河谷-山地森林交错带植物光合生理特征对干旱胁迫的响应。以交错带两种典型植物高山柳(Salix paraqplesia)和沙棘(Hippophae rhamnoides)为研究对象,研究其在不同程度的干旱胁迫条件下植株气体交换参数的日变化特征。干旱胁迫显著降低了两种植物叶片数、叶面积、叶片生物量、比叶面积、色素含量、净光合速率(Pn)、气孔导度(gs)和气孔限制值(Ls)等与光合生理过程密切相关的叶片指标,但增大了胞间CO₂浓度(Ci)和内禀水分利用效率(WUEi)。植物叶片的气体交换参数(如:Pn和gs)日变化并未完全随着光合有效辐射的增强和温度的升高而增加,全天以11:00最大,"午休"现象明显。相对而言,沙棘在干旱胁迫条件下表现出相对较高的叶面积、Pn、gs和WUEi,具有相对更强的适应干旱环境的能力,而高山柳对干旱胁迫更为敏感。     

干旱胁迫对玉米苗期叶片光合作用和保护酶的影响

以玉米品种郑单958(抗旱性强)和陕单902(抗旱性弱)为材料,采用盆栽控水试验,设置3个干旱处理(轻度干旱,中度干旱,重度干旱)和正常灌水,研究了干旱胁迫对玉米苗期叶片光合速率、叶绿素荧光以及相关生理指标的影响。结果表明:(1)干旱胁迫下2个品种叶片净光合速率(P_n)和气孔导度(G_s)显著下降,胞间CO₂浓度(C_i)出现了先下降后上升,而气孔限制值(L_s)上升后下降,说明中度干旱胁迫下叶片P_n下降是气孔因素引起的,重度干旱胁迫下P_n降低主要由非气孔因素引起的。(2)随着干旱胁迫的加剧,2个品种叶片光系统Ⅱ(PSⅡ)的实际量子产量(φPSⅡ)、电子传递速率(ETR)和光化学猝灭(qP)一直下降,而非光化学猝灭(qN)上升后下降,说明中度干旱下热耗散仍是植株重要光保护机制,重度干旱时叶片光合电子传递受阻,PSⅡ受到损伤。(3)干旱胁迫下2个品种叶片的超氧化物歧化酶(SOD)、过氧化物酶(POD)、过氧化氢酶(CAT)活性先升高后降低,而丙二醛(MDA)含量一直升高,说明干旱胁迫初期对保护系统酶活性升高有诱导作用,重度胁迫下活性氧清除酶的活性下降,导致细胞膜伤害。这些结果暗示,轻度和中度干旱胁迫下2个玉米品种通过减少光捕获、热耗散和酶活性调节协同作用稳定了光合机构功能,是P_n下降的气孔限制因素;而重度干旱胁迫下光系统Ⅱ和抗氧化酶系统损伤,是P_n下降的非气孔限制因素;郑单958的各生理参数比陕单902受旱影响小,干旱胁迫下仍具有较高的光合效率和较强的保护酶活性是郑单958抗旱的主要生理原因。     

干旱胁迫下4种常用植物幼苗的光合和荧光特性综合评价

老鸭嘴,山毛豆,假连翘和葛藤是常见的矿山植被恢复植物。采用盆栽控制土壤水分的方法,测定了这 4 种幼苗叶片的光合和荧光指标,以期为矿山植被的恢复植物筛选提供依据。结果表明（1）干旱胁迫处理期间,4 种幼苗叶片的净光合速率（P_n）、气孔导度（G_s）、蒸腾速率（T_r）和胞间CO₂ 浓度（C_i）持续下降,复水8 d后P_n均显著增加,老鸭嘴和山毛豆的G_s和T_r恢复到对照水平,山毛豆和葛藤的C_i恢复到对照水平;假连翘幼苗叶片的气孔限制值（L_s）随干旱胁迫时间的延长而逐渐增加,其他3 种幼苗略降后增加,复水8 d后均恢复到对照水平。（2）干旱胁迫处理期间,4 种幼苗叶片的photosystemⅡ（PSⅡ）光能捕获效率（F_v’/F_m’）、实际光化学量子效率（Yield）和表观电子传递速率（ETR）持续降低,8 d时显著小于对照。复水8 d后,F_v’/F_m’小幅波动,Yield和ETR有所恢复,其中葛藤的Yield和山毛豆的ETR恢复到对照水平;4种幼苗叶片的非化学淬灭（NPQ）持续上升,在第8天显著大于对照,复水8 d后,均持续下降,其中葛藤恢复到对照水平。（3）对光合和荧光指标进行主成分分析表明,干旱胁迫下4 种幼苗的抗旱性能大小顺序为山毛豆 > 老鸭嘴 > 假连翘 > 葛藤。     

低硫氮比酸雨对亚热带典型树种气体交换和质膜的影响

通过对我国亚热带典型树种香樟(Cinnamomum camphora)、木荷(Schima superba)和枫香(Liquidambar formosana)1年生幼苗为期4个月的模拟酸雨处理,以当地水库水为对照,研究硫氮比(摩尔比)为1.58的酸雨胁迫(中度酸雨pH3.5、重度酸雨pH2.5)下植物气体交换参数、光合色素含量、质膜透性和丙二醛含量等生理指标的变化规律。结果表明:中度酸雨对植物的气体交换和质膜没有造成明显影响。重度酸雨导致叶片净光合速率、气孔导度、蒸腾速率和水分利用效率下降;植物叶片的质膜透性和丙二醛含量显著上升;重度酸雨的氮肥效应虽提高了叶片叶绿素含量,但单位叶绿素的净光合速率仍下降明显。与以往高硫氮比(摩尔比>6)酸雨胁迫研究相比,低硫氮比可能会减缓中度酸雨(pH3.5)对植物气体交换和质膜的负面影响;但是当pH值降至2.5时,酸雨仍然会造成植物气孔部分关闭,膜系统损伤,叶绿素光合活性下降,并最终抑制植物光合作用。     

基于叶绿体基因组数据的芸香科属间系统发育初步分析（专题约稿）

该研究在人工控制水分条件下,设置3个干旱胁迫处理,选用3个主栽油菜品种‘陇油10号’、‘陇油2号’、‘青杂5号’幼苗进行盆栽试验,测定干旱胁迫条件下叶片相对含水量、叶绿素含量、光合气体交换参数及叶绿素荧光参数等指标,考察各指标在干旱胁迫过程中的变化特征,并通过主成分分析(PCA)和隶属函数法评价品种的抗旱性及其主要响应因子,以揭示西北地区油菜幼苗响应干旱胁迫的光合调控机制。结果表明：(1)各品种油菜幼苗的叶片相对含水量(RWC)均随干旱胁迫程度的递增而逐渐降低,最大水分亏缺(WSD)却逐渐上升。(2)各品种油菜幼苗叶片的叶绿素a含量、叶绿素总含量随着干旱胁迫程度的递增而先增加后递减,且同一种幼苗在不同处理间差异显著。(3)各品种油菜幼苗叶片的净光合速率(P_n)、水分利用效率(WUE)、单株生物量、气孔导度(G_s)、胞间CO₂浓度(C_i)均在受到干旱胁迫时迅速降低,且同一品种幼苗在不同处理间差异显著,而其叶片蒸腾速率(T_r)在干旱胁迫下无显著变化。(4)各品种油菜幼苗叶片光化学猝灭系数(qP)和非光化学猝灭系数(NPQ)随着干旱胁迫程度的递增先增加后递减,最大光化学效率(F_v/F_m)和电子传递速率(ETR)在受到干旱胁迫时迅速降低,且同一品种幼苗在不同处理间差异显著。(5)主成分分析结果表明,在油菜幼苗受到干旱胁迫时RWC、C_i、G_s、P_n、WUE、叶绿素总含量、叶绿素a含量和NPQ起主要调控作用;隶属函数法综合评价表明,3个品种油菜幼苗耐旱能力由高到低依次为‘陇油10号’＞‘陇油2号’＞‘青杂5号’。     

施氮量对麻疯树幼苗生长及叶片光合特性的影响

采用盆栽土培的方法,研究了不同施氮量(对照N₀ 0 kg N/hm²、低氮N_L 96 kg N/hm²、中氮N_M 288 kg N/hm²、高氮N_H 480 kg N/hm²)对麻疯树幼苗生长、叶片气体交换及叶绿素荧光参数的影响。结果表明,麻疯树幼苗叶片氮含量、可溶性蛋白含量、株高、地径、叶片数量、叶面积、根长、各组分生物量、叶片净光合速率(P_n)、气孔导度(G_s)、蒸腾速率(T_r)和水分利用效率(WUE)均随施氮量的增加先升高后降低,N_M处理下麻疯树幼苗长势最好,各气体交换参数值最高;施氮对麻疯树地上部分的促进作用远大于地下部分,施氮后根冠比显著降低;此外,麻疯树叶绿素含量、PSⅡ最大光化学量子产量(Fv/Fm)、PSⅡ有效量子产量(F'v/F'm)、PSⅡ实际光化学效率(Φ_PSⅡ)、电子传递速率(ETR)和光化学淬灭系数(qP)均随施氮量的增加而升高,非光化学淬灭系数(NPQ)随施氮量增加而降低。适量施氮可通过增强叶绿体光化学活性、气孔导度和羧化能力而提高麻疯树幼苗的光合能力,促进生长;过高施氮对麻疯树幼苗光合与生长的促进效应降低。试验条件下,当年生麻疯树幼苗的最适施氮量为288 kg N/hm²。     

女贞和珊瑚树叶片表面特征的AFM观察

应用原子力显微镜观察了女贞(Ligustrum lucidum)、珊瑚树(Viburnum odoratissimum)幼叶和成熟叶的表面特征,并探讨了叶面微结构对滞尘能力的可能影响以及抵抗干旱、污染物等胁迫的能力。女贞幼叶和成熟叶正背面的粗糙度Ra分别为417.8、794.5,1069、957.4 nm;珊瑚树幼叶和成熟叶正背面的粗糙度Ra分别为471.3、469.6,291.1、865.9 nm。和幼叶相比,成熟叶表面的粗糙度发生变化,但2个物种的变化趋势不同,这种变化可能与气孔的发育以及外界环境条件对叶片表面形态结构、蜡质含量和成分的影响不同有关。叶片表面存在大量的沟状、孔状峰谷区域和直径约为10 μm的凹陷,有利于PM₁₀的滞留。女贞和珊瑚树成熟叶气孔只分布在叶下表皮且下陷。这些特征均说明女贞和珊瑚树具有较强的滞尘能力和抵抗干旱、污染物胁迫的能力,作为绿篱植物对消减城市大气颗粒物污染和提高空气质量具有重要的意义。     

干旱胁迫下巨尾桉的形态可塑性和生理响应特征

以1月龄巨尾桉组培苗为材料,通过模拟雨季和旱季的土壤水分条件试验探讨干旱胁迫下巨尾桉幼苗形态的可塑性及生理响应特征.结果表明:与高水和中水处理相比,低水处理(13%左右土壤体积水分含量,模拟旱季土壤水分)导致巨尾桉幼苗生物量减少,叶片形态发生明显变化,总叶面积、叶片数、平均叶面积和比叶面积减少,而且叶片可溶性糖含量增加;但水分胁迫下巨尾桉生物量分配模式不变,叶片脯氨酸含量变化也不明显,叶片最大光化学量子效率(Fv/Fm)仍维持在正常水平.研究发现,干旱并未对巨尾桉光合能力和水分吸收策略造成过多影响,巨尾桉能通过限制生长、减少水分消耗来应对干旱胁迫,保证植株安全度过干旱同时又不会过度消耗当地环境水分,以利于维持当地旱季的水分平衡.     

马尾松人工林近自然化改造对植物自然更新及物种多样性的影响

中国人工林面积居世界第一位,而马尾松是中国人工林面积较大的树种之一,广泛分布于中国的亚热带区域。马尾松适应能力强,耐干旱、瘠薄,是南方低山丘陵区群落演替的先锋树种,也是荒山绿化造林的主要树种,马尾松人工林对生态防护、生态治理有着重大的意义。但是,绝大部分马尾松人工林为人工纯林,生态系统比较脆弱,生态服务功能较差。人工林的近自然改造对于增加林地生物多样性,提升人工林的生态服务功能具有重要意义。2005年,对中国林业科学院热带林业试验中心1993年造林的马尾松人工林进行4种不同强度(50%、40%、30%、20%)间伐后,套种大叶栎(Castanopsis fissa)、米老排(Mytilaria laosensis)、润楠(Machilus pingii)、红锥(C. hystrix)4个乡土阔叶树种,各种套种密度皆为120株/hm²。分别于间伐前(2004年)及2010年对群落生物多样性及人工套种树种生态情况进行调查,结果表明:(1)间伐处理后,自然更新至乔木层的物种种类和数量都有显著的增加,600 m²的样方中,物种数由(2.75±2.56)种增加到(11.17±4.32)种,个体数由(5.75±4.31)株增加到(32.17±19.09)株,群落中乔木亚层的优势种变化不大,主要有南酸枣(Choerospondias axillaris)、水锦树(Wendlandia uvariifolia),枫香(Liquidambar formosana)、破布木(Cordia dichotoma)、白背桐(Mallotus paniculatus)等。新增加到乔木层的物种大都为之前群落中灌木层的种类,主要有三桠苦(Evodia lepta)、鸭脚木(Schefflera minutistellata)、白花龙(Styrax faberi)、中平树(Macaranga denticulata)、黄毛榕(Ficus esquiroliana)、华南毛柃(Eurya ciliata)、罗浮柿(Diospyros morrisiana)、猴耳环(Pithecellobium clypearia)、木姜子(Litsea pungens)、毛黄肉楠(Actinodaphne pilosa)等。(2)间伐处理前,600 m²样方中出现的灌草种类数量为(24.63±4.24)种,间伐处理后,600 m²样方中出现的灌草种类数量为(27.58±3.80)种,不同间伐强度处理后林下灌草的优势种与间伐前大致相同,灌木层优势种为三桠苦,草本层优势种为弓果黍(Cyrtococcum patens)。不同间伐强度处理林分间,灌木层和草本层的物种丰富度指数、Shannon-Wiener指数、Simpson指数和Pielou指数均无显著差异,且与间伐前林分也无显著差异。(3)间伐促进了4个乡土树种幼树的生长,随着间伐强度的增加,大叶栎、红锥幼树的高度和胸径显著增长;50%的间伐强度的林分中,阔叶树种幼树的长势要显著好于其他间伐强度,50%的间伐强度最有利于马尾松林下套种的阔叶树种生长。(4)在马尾松林下套种的4个阔叶树种幼树的初期生长有明显差异。总体而言,大叶栎与米老排幼树的早期生长速率要明显高于红锥和润楠。     

Drought‐related tree death of savanna eucalypts: Species susceptibility,soil conditions and root architecture

Questions: For eucalypt savanna in northeast Australia subject to multi‐year rainfall deficits this paper asks whether (1) dominant tree species (Ironbarks, Boxes) are more drought susceptible than the sub‐dominant Bloodwoods; (2) whether soil moisture is beyond wilting point in surface soil layers but available at depth; (3) soil conditions (moisture availability and texture) are related to tree death during drought; (4) the root systems of the Boxes and Ironbarks are shallower than the Bloodwoods; and the survivors of drought within species have deeper root systems than those that died. Location: Central Queensland, Australia. Methods: Patterns of tree death between eucalypt species were compared from field data collected after drought. Soil conditions during drought were described and compared with patterns of tree death for the Ironbark Eucalyptus melanophloia. The basal area and orientation of coarse roots were measured on upturned trees after broad‐scale tree clearing, and compared between species, and between live and dead trees with tree size as a covariate. Results: Drought‐induced tree death was higher for dominant Ironbark‐Box than for sub‐dominant Bloodwoods. During a moderate to severe drought in 2004, 41% of 100 cm deep subsoils had soil matric potential less than‐5600 kPa. The drought hardy Bloodwoods had a greater root basal area and particularly so for vertical roots compared to the drought sensitive Ironbark‐Box. Within species there was no significant difference in root basal area characteristics between trees that were recently killed by drought and those that remained relatively healthy. Surface soil moisture availability was lower where tree densities were high, and tree death increased as surface soil moisture became less available. Tree death was also greater as the clay content of sub‐soils increased. Discussion: The study suggests species with roots confined to upper soil layers will suffer severe water stress. The results strongly indicate that root architecture, and the way it facilitates water use during drought, is important for the relative dominance of the tree species. Patchiness in drought‐induced tree death seems to be at least partially a product of heterogeneity in sub‐soil conditions and competition for soil moisture.     

Can tree species richness attenuate the effect of drought on organic matter decomposition and stabilization in young plantation forests?

Changes in precipitation due to climate change are likely to influence soil organic matter (SOM) decomposition and stabilization. In forests, increased tree species diversity could modulate the effects of drought on SOM decomposition and stabilization. We addressed this issue by a decomposition study under simulated drought (through precipitation reduction at Zedelgem, Belgium) and natural drought (ORPHEE, southern France) in young experimental plantations (tree species richness 1 to 5). In Zedelgem, the study focused on tree species richness around oak and beech trees. Two tea bag indices (TBI) – decomposition rate (k) and stabilization factor (S) – were calculated by measuring the decay of green and rooibos tea in soils. Overall, TBI's were higher in Zedelgem than at ORPHEE. In Zedelgem, k increased with tree species richness under drought around oak, indicating that tree species richness modulated the effects of drought on decomposition. Under beech, k decreased with drought while no effect of tree species richness was detected. S increased with drought under both oak and beech, without any effect of tree species richness. In ORPHEE, we did not detect any tree species richness effect on both TBIs. S decreased significantly, while k was marginally reduced under drought. The higher S under drought in Zedelgem and under control in OPRHEE suggests that the carbon sequestration potential under climate change would be dependent on the environmental context. Further, in young plantations, high species richness may modulate the drought effect on SOM decomposition, but not on stabilization.     

Know Your Neighbours: Drought Response of Norway Spruce,Silver Fir and Douglas Fir in Mixed Forests Depends on Species Identity and Diversity of Tree Neighbourhoods

Norway spruce is a widely cultivated species in Central Europe; however, it is highly susceptible to droughts, which are predicted to become more frequent in the future. A solution to adapt spruce forests to droughts could be the conversion to mixed-species stands containing species which are less sensitive to drought and do not increase the drought stress in spruce. Here we assessed the drought response of spruce and the presumably more drought-tolerant silver fir and Douglas fir in mixed-conifer stands. We measured tree ring widths of 270 target trees, which grew in mixed and mono-specific neighbourhoods in 18 managed stands in the Black Forest, to quantify the complementarity effects caused by species interactions on growth during the extreme drought event of 2003 and for a number of years with “normal” growth and climatic conditions. Mixed-species neighbourhoods did not significantly affect tree ring growth in normal years. However, during the drought, silver fir benefitted from mixing, while Douglas fir was more drought-stressed in the mixture. The drought response of spruce was dependent on the density and species composition of the neighbourhood, showing both positive and negative mixing effects. Mixed stands containing these tree species could improve adaptation to drought because the risks of extreme events are spread across species, and the performance of individual species is improved. Our knowledge about specific species interactions needs to be improved to manage tree mixtures more effectively with regard to the participating species and stand density.     

Forest resistance to drought in a humid tropical dipterocarp forest in the Western Ghats of India

Droughts are linked to tree die-offs in the biodiverse humid tropics. We assessed drought response of a Dipterocarp Forest and found a marginal decrease in tree survival, indicating drought resistance. Understory and emergent species were sensitive to drought. Urgent focus is needed to understand drought impacts and plant physiological responses in South Asian forests.     

Different responses of multispecies tree ring growth to various drought indices across Europe

Increasing frequency and intensity of drought extremes associated with global change are a key challenge for forest ecosystems. Consequently, the quantification of drought effects on tree growth as a measure of vitality is of highest concern from the perspectives of both science and management. To date, a multitude of drought indices have been used to accompany or replace primary climatic variables in the analysis of drought-related growth responses. However, it remains unclear how individual drought metrics compare to each other in terms of their ability to capture drought signals in tree growth.In our study, we employ a European multispecies tree ring network at the continental scale and a set of four commonly used drought indices (De Martonne Aridity Index, self-calibrating Palmer Drought Severity Index, Standardized Precipitation Index and Standardized Precipitation Evapotranspiration Index, the latter two on varying temporal scales) to derive species-specific growth responses to drought conditions. For nine common European tree species, we demonstrate spatio-temporal matches and mismatches of tree growth with drought indices subject to species, elevation and bioclimatic zone. Forests located in the temperate and Mediterranean climate were drought sensitive and tended to respond to short- and intermediate-term drought (<1 year). In continental climates, forests were comparably more drought resistant and responded to long-term drought. For the same species, stands were less drought sensitive at higher elevations compared to lower elevations. We provide detailed information on the month-wise performance of the four drought indices in different climate zones allowing users the selection of the most appropriate index according to their objective criteria. Our results show that species-specific differences in responses to multiple stressors result in complex, yet coherent patterns of tree growth.     

Legacies of more frequent drought in ponderosa pine across the western United States

Despite widespread interest in drought legacies—multiyear impacts of drought on tree growth—the key implication of reported drought legacies remains unaddressed: as impaired growth and slow recovery associated with drought legacies are pervasive across forest ecosystems, what is the impact of more frequent drought conditions? We investigated the assumption that either multiple drought years occurring during a short period (multiyear droughts), or droughts occurring during the recovery period from previous drought (compounded droughts), are detrimental to subsequent growth. There is evidence that drought responses may vary among populations of widespread species, leading us to examine regional differences in responses of the conifer Pinus ponderosa to historic drought frequency in the western United States. More frequent drought conditions incurred additional growth declines and shifts in growth–climate sensitivities in the years following drought relative to single‐drought events, with ‘triple‐droughts' being worse than ‘double‐droughts'. Notably, prediction skill was not strongly reduced when ignoring compounded droughts, a consequence of the temporally comprehensive formulation of our stochastic antecedent model that accounts for the climatic memory of tree growth. We argue that incorporating drought‐induced temporal variability in tree growth sensitivities can aid inference gained from statistical models, where more simplistic models could overestimate the severity of drought legacies. We also found regional differences in response to repeated drought, and suggest plastic post‐drought sensitivities and climatic memory may represent beneficial physiological adjustments in interior regions. Within‐species variability may thus mediate forest responses to increasing drought frequency under future climate change, but experimental approaches using more species are necessary to improve our understanding of the mechanisms that underlie drought legacy effects on tree growth.     

Dominant tree species are at risk from exaggerated drought under climate change

Predicting the consequences of climate change on forest systems is difficult because trees may display species‐specific responses to exaggerated droughts that may not be reflected by the climatic envelope of their geographic range. Furthermore, few studies have examined the postdrought recovery potential of drought‐susceptible tree species. This study develops a robust ranking of the drought susceptibility of 21 tree species based on their mortality after two droughts (1990s and 2000s) in the savanna of north‐eastern Australia. Drought‐induced mortality was positively related to species dominance, negatively related to the ratio of postdrought seedlings to adults and had no relationship to the magnitude of extreme drought within the species current geographic ranges. These results suggest that predicting the consequences of exaggerated drought on species’ geographic ranges is difficult, but that dominant species like Eucalyptus with relatively slow rates of population recovery and dispersal are the most susceptible. The implications for savanna ecosystems are lower tree densities and basal area.     

出露基岩生境典型植物树干液流对自然降水和连续干旱的响应特征

以西南喀斯特地区常见的出露基岩生境为研究对象,针对该类生境典型乔木类植物菜豆树和圆叶乌桕,应用TDP热扩散探针技术,结合遮雨试验,分析了植物树干液流对自然降水和连续干旱的响应特征.结果表明:在生长季不同时期,降水后2树种液流密度较降水前均有一定程度的升高,但始终呈现落叶乔木圆叶乌桕高于半落叶乔木菜豆树的特征;连续2个月遮雨条件下,2树种液流密度均无明显降低的趋势,表明2树种均不依赖受近期降水主导的水源;通过对降水前后及连续干旱条件下2树种液流密度与环境因子的拟合关系研究发现,气象因素差异对水分环境变化条件下植物蒸腾耗水的影响较小.自然降水和短时期的连续干旱并未显著改变2树种的蒸腾耗水特征,这可能与出露基岩生境特殊的水分蓄持环境和乔木类植物依赖相对稳定的深层水源有关.     

华北低山丘陵区常用树种木质部解剖特征及水其力学抗旱性

木本植物木质部解剖特征与水分运输和干旱适应策略密切相关,但目前对华北低山丘陵区常用树种这方面的研究仍然不足。为研究这一地区植物木质部解剖特征与抗旱性的关系,研究以抗旱树种和非抗旱树种各5种为研究对象,通过测定与木质部横截面导管、薄壁组织相关的大量解剖学性状和非结构性碳浓度,比较两类树种木质部解剖特征的差异和解剖性状间的关联,以探究这些树种水力学的干旱适应策略差异。结果显示:1)10个树种的16个木质部性状均有较大变异性;2)两类树种间的平均导管直径和导管密度无显著差异,但抗旱树种导管壁厚度、最大导管直径、旁管薄壁组织比例和轴向薄壁组织比例以及非结构性碳(NSC)浓度显著大于非抗旱树种;3)抗旱树种的导管壁厚度与平均导管直径、最大导管直径和潜在最大导水率均呈显著正相关关系,最大导管直径与潜在最大导水率呈显著正相关关系,但非抗旱树种不存在这些关系。本研究抗旱树种同时具有较大的最大导管直径和较厚的导管壁,在保证较高的水分运输效率的同时又具备一定的抗栓塞能力,较多的旁管薄壁组织和NSC也为抗旱树种提供了更大的木质部水储存和栓塞修复能力。     

Patterns of drought tolerance in major European temperate forest trees: climatic drivers and levels of variability

The future performance of native tree species under climate change conditions is frequently discussed, since increasingly severe and more frequent drought events are expected to become a major risk for forest ecosystems. To improve our understanding of the drought tolerance of the three common European temperate forest tree species Norway spruce, silver fir and common beech, we tested the influence of climate and tree‐specific traits on the inter and intrasite variability in drought responses of these species. Basal area increment data from a large tree‐ring network in Southern Germany and Alpine Austria along a climatic cline from warm‐dry to cool‐wet conditions were used to calculate indices of tolerance to drought events and their variability at the level of individual trees and populations. General patterns of tolerance indicated a high vulnerability of Norway spruce in comparison to fir and beech and a strong influence of bioclimatic conditions on drought response for all species. On the level of individual trees, low‐growth rates prior to drought events, high competitive status and low age favored resilience in growth response to drought. Consequently, drought events led to heterogeneous and variable response patterns in forests stands. These findings may support the idea of deliberately using spontaneous selection and adaption effects as a passive strategy of forest management under climate change conditions, especially a strong directional selection for more tolerant individuals when frequency and intensity of summer droughts will increase in the course of global climate change.