峨眉冷杉幼苗叶片功能特征及其N、P化学计量比对模拟大气氮沉降的响应

通过人工施氮模拟大气氮沉降,研究了施氮对峨眉冷杉(Abies fabiri)幼苗叶片功能特征、氮和磷含量及其化学计量比的影响,以及幼苗对氮素的积累效应。结果表明:经过2个生长季节的施氮处理(2009年和2010年,N2)幼苗的总生物量、叶干重、叶重比、叶片氮和磷含量及其N:P分别高于对照处理11.29%、46.70%、41.40%、37.30%、22.33%和6.43%,而比叶面积则降低了6.61%,其中叶干重、叶重比和叶片氮含量与对照处理差异显著(P<0.05),N:P差异极显著(P<0.01),并且叶干重与叶片氮含量具有较强的线性相关;与经1个生长季节施氮处理(2009年,N1)的幼苗总生物量、叶干重、叶重比、比叶面积、叶片氮和磷含量及其N:P的比较分析表明,除叶重比和比叶面积外,其他指标N2均高于N1;人工施氮显著促进了幼苗叶片的生长,提高了叶片氮、磷含量及其N:P,但也反映幼苗生长仍受氮素限制,同时,峨眉冷杉幼苗具有氮素积累效应。     

长期模拟增温对岷江冷杉幼苗生长与生物量分配的影响

川西亚高山针叶林是青藏高原东部高寒林区的重要组成部分,也是研究全球变化对森林生态系统影响的重要组成。长期模拟增温对川西亚高山森林树木的生长、物质积累及其分配格局的影响至今鲜有报道。以川西亚高山针叶林优势种岷江冷杉(Abies faxoniana)幼苗为研究对象,采用控制环境生长室模拟增温的方法,研究了模拟增温对岷江冷杉幼苗生长、物质积累及其分配格局的影响。结果表明,模拟增温(2.2±0.2)℃处理65个月后,岷江冷杉幼苗基径、株高、单株叶面积和比叶面积(SLA)均显著增加,比叶重(LMA)显著下降。增温对岷江冷杉幼苗的茎、侧枝、叶和总生物量具有显著的促进作用,对根生物量没有显著影响。岷江冷杉幼苗的叶重比(LMR)下降、枝重比(SMR)增加、根重比(RMR)无显著变化。长期增温能显著促进岷江冷杉幼苗的生长和物质积累,改变生物量分配格局,促使叶片物质向茎转移,降低光合物质投入。     

模拟增雨对白刺和油蒿幼苗化学计量特征的影响

降雨是荒漠生态系统过程和功能的最重要限制因子,荒漠植物幼苗对生长季降雨的变化极端敏感。为探讨荒漠植物对未来降雨格局变化的响应,该研究选取乌兰布和沙漠2种典型荒漠植物幼苗(白刺和油蒿)为研究对象,根据生长季内(6～9月)每次降雨量,进行不同梯度的人工模拟增雨试验(CK.自然降雨;A.增雨25%;B.增雨50%;C.增雨75%;D.增雨100%),分析白刺和油蒿幼苗C、N、P含量及化学计量特征对降雨量变化的响应。结果表明:(1)从C、N、P含量在幼苗不同器官分布来看,与CK相比,增雨显著降低了白刺幼苗茎的C含量和根的C、P含量(P0.05),在一定程度上提高了叶的C、P含量和根的N含量;而增雨处理显著增加了油蒿幼苗茎和叶的C含量(P0.05),降低了叶、根的N含量和茎、叶、根的P含量。(2)从化学计量比来看,增雨对白刺幼苗茎、叶、根的N∶P影响无显著差异,比值均大于16,且在增雨的环境下白刺幼苗相对生长率较低,主要受P元素限制;油蒿幼苗根N∶P与增雨量呈极显著负相关关系,随增雨量的增加其相对生长率增大。研究认为,模拟增雨对白刺幼苗和油蒿幼苗化学计量特征均有显著影响,但二者幼苗C、N、P元素在各器官的分配格局有所不同,增雨不利于白刺幼苗的生长,而有利于油蒿幼苗的快速生长。     

光照和氮磷供应比对木荷生长及化学计量特征的影响

光照和养分限制是影响林下植物生长和更新的关键影响因素,以亚热带主要常绿树种木荷（Schima superba）实生幼苗为试验对象,研究了不同光照（全光照、遮阴即45%全光照）和N、P供应比例（5,15,45）对幼苗生长和化学计量特征的影响。结果表明：（1）遮阴不仅严重抑制了木荷各器官和单株生物量积累,更加剧了P限制。尽管N、P添加对木荷生长没有显著促进作用,但N、P供应比例为5时的性状组合更有利于木荷后期生长,但高N、P供应比例可能导致P限制。（2）遮阴下叶N、P含量显著增加,但叶C/N和C/P比显著降低;不同光照处理组中各器官及总N含量均随N、P供应比例增大而显著增加,而C/N比逐渐降低;P的分配格局发生改变,全光照组各器官P含量为茎 > 叶 > 根,遮阴组各器官P含量为根 > 茎 > 叶。（3）随N、P供应比例增加或光照强度降低,木荷均趋向降低根冠比和根质比、增加叶质比或茎质比。（4）木荷生物量与各器官N、P含量、叶质比呈极显著负相关,而与C/N和C/P比及根冠比、茎质比、根质比呈极显著正相关。光强和N、P比例变化均显著影响了木荷幼苗的养分利用特征,因而木荷作为伴生树种优化林分环境对其早期生长具有重要意义。     

川西林线交错带岷江冷杉幼苗异龄叶形态对长期模拟增温的响应

全球气候变暖对高纬度、高海拔地区的植物形态产生强烈影响。川西林线交错带是青藏高原东部高寒生态系统的重要组成部分,对全球变化极度敏感。以川西林线交错带岷江冷杉(Abies faxoniana)幼苗异龄叶为对象,采用原位开顶式生长室(Open-top chamber,OTCs)模拟增温,研究了长期模拟增温下岷江冷杉幼苗异龄叶片叶长、叶厚等叶形态的响应,采用表型可塑性指数和变异系数对叶形态的可塑性进行分析。结果表明:增温限制岷江冷杉幼苗叶片的增长、增宽和叶面积、体积的扩大,使叶长、叶宽、叶面积、叶体积分别较对照减小12.77%、11.86%、17.76%、11.49%;增温促进叶片厚度的增加,较对照增加7.27%;除叶长宽比外,增温对其余叶形态均产生显著影响(P0.05)。叶形态对模拟增温的响应具有显著的年龄差异(P0.05)。温度、叶龄的交互效应对叶长和叶面积影响显著(P0.05),对叶宽和叶厚影响不显著(P0.05)。两种表型可塑性分析结果表明,除1 a叶叶长外,增温不同程度增大各叶形态可塑性。长期增温使冷杉幼苗叶片有旱生倾向且形态值更发散。研究提供了岷江冷杉幼苗叶片对长期增温的差异性响应证据,为评估青藏高原东缘优势植物对响应气候变暖提供了基础数据和理论参考。     

凋落物和增温联合作用对峨眉冷杉幼苗抗氧化特征的影响

峨眉冷杉林是青藏高原东缘亚高山暗针叶林的重要组成部分,其自然更新对全球变化非常敏感,是研究气候变化对陆地生态系统影响的代表性森林类型.以峨眉冷杉幼苗为研究对象,以开顶式增温小室(Open top chambers,OTCs)和电热棒联合的方式增加环境温度,人为添加不同类型凋落物(A,75％峨眉冷杉针叶+25％杜鹃荚蒾灌木叶凋落物;B,55％峨眉冷杉针叶+45％杜鹃荚蒾灌木叶凋落物),共设置4个处理:(1)凋落物A+增温T(A-T);(2)凋落物B+增温T(B-T);(3)凋落物A+环境温度TO(A-T0);(4)凋落物B+环境温度TO(B-TO).研究增温和两种类型凋落物联合作用下峨眉冷杉幼苗的生理生态响应特征.得到以下结果:(1)在环境温度下,A型凋落物情景下的冷杉幼苗的电导率、丙二醛和脯氨酸含量、超氧阴离子自由基产生率比B型情景下高;而可溶性糖和淀粉含量、超氧化物歧化酶(SOD)、抗坏血酸过氧化物氢酶(APX)和过氧化氢酶(CAT)活性比B型凋落物情景下低.说明在当前环境温度下,B型凋落物比A型凋落物更加适合冷杉幼苗的生长.(2)在A型凋落物情景下,增温处理显著增加了冷杉幼苗叶片的自由脯氨酸含量和过氧化氢浓度;在B型凋落物情景下,增温处理显著降低了冷杉幼苗丙二醛、自由脯氨酸含量、可溶性糖和淀粉含量,增加了超氧阴离子自由基产生速率.可见,与A型凋落物相比,增温使得B型凋落物情景下的冷杉幼苗膜伤害程度减小.(3)不同类型凋落物与增温的联合作用均降低了冷杉幼苗的可溶性糖和淀粉含量.与A-T处理相比,B-T处理下冷杉幼苗叶片的电导率、丙二醛和脯氨酸含量更低,而POD、APX、GR、CAT抗氧化酶活性却更高.研究结果表明,针叶成分相对较少的B型凋落物更有利于峨眉冷杉幼苗适应未来气候变暖情景.     

干旱胁迫下接种丛枝菌根真菌对七子花非结构性碳水化合物积累及C、N、P化学计量特征的影响

以濒危植物七子花二年生幼苗为研究材料,采用盆栽试验方法,研究干旱胁迫和接种丛枝菌根真菌(AMF)处理对幼苗不同器官C、N、P化学计量关系和非结构性碳水化合物(NSC)含量的影响。试验共设计4个处理:对照(CK)、干旱胁迫(D)、接种AMF(AMF)、干旱胁迫和接种AMF(D+AMF)。结果表明: 在干旱胁迫下七子花根系AMF的侵染率显著下降,但接种AMF处理植株的株高、叶片数显著高于未接种处理。接种AMF显著提高了干旱胁迫下植株根、叶可溶性糖和NSC含量及茎、叶淀粉含量,且茎和叶可溶性糖与淀粉比显著下降。干旱胁迫导致植株C含量在根和叶中显著增加,P含量在茎中显著减少;与干旱胁迫相比,胁迫下接种AMF植株根、茎、叶P含量及叶C含量显著提高,而根C、N含量及茎C含量显著降低。胁迫下接种AMF植株根、茎C∶N、C∶P、N∶P和叶N∶P均显著低于单一胁迫处理。NSC与C∶N∶P计量比的相关性分析表明,根、叶P含量与可溶性糖和NSC含量呈显著正相关,茎P含量与淀粉和NSC含量呈显著正相关,各器官N∶P与NSC含量呈显著负相关。综上,干旱胁迫显著抑制了七子花幼苗的生长,接种AMF通过提高植株根和叶的可溶性糖含量、根的可溶性糖/淀粉,增加地上部分淀粉含量,促进P元素吸收和降低各器官N∶P来增强植株耐旱性,从而提高七子花幼苗在干旱环境中的存活率。     

遮荫对青桐幼苗生长性状与化学计量特征的影响

营养元素含量及化学计量比可反映植物器官营养元素的分配及互作关系,亦可反映其营养利用效率及生长环境的养分限制状况。以青桐(Firmiana platanifolia)幼苗为材料,分析4种不同光强(全光照,50%、75%和95%遮荫)对青桐幼苗生长,C、N、P、K含量及其化学计量特征的影响。结果表明:遮荫对青桐幼苗的生长性状、生物量、元素含量和积累量及化学计量比均有显著影响(P<0.05)。苗高和比叶面积随遮荫强度增加而升高,而地径和粗壮度随遮荫强度增加而减小。总生物量在75%遮荫下最大,在95%遮荫下最小。在各遮荫处理下,叶片C、N、P、K含量均大于根和茎,且N含量顺序为叶>根>茎,K含量顺序为叶>茎>根。C、P、K积累量随遮荫强度增大而增加,在75%遮荫下达到最大值,而在95%遮荫下达到最小值。青桐幼苗C∶N和C∶P呈现出相同的变化趋势,随遮荫强度变大先增加后减小,均在50%遮荫下达最大值。青桐各器官N∶P远低于14,即青桐幼苗在不同遮荫条件下的生长严重受N限制。这些结果说明,遮荫可调节青桐幼苗在不同光环境中的养分积累与分配,进而影响生物量。因此,青桐苗期培育宜选75%遮荫,有助于苗高、比叶面积、生物量、养分含量和积累量的增加,而过度遮荫可抑制幼苗生长发育。     

干旱胁迫对科尔沁沙地榆树幼苗C、N、P化学计量特征的影响

设置适宜水分、轻度、中度和重度干旱胁迫处理(即80%、65%、50%和35%田间持水量),研究干旱胁迫对榆树幼苗不同器官C、N、P化学计量的影响.结果表明:与适宜水分处理相比,干旱胁迫导致C含量在叶、茎、粗根和细根中增加,N含量在叶、茎和粗根中增加,P含量在叶、茎和粗根中下降,在细根中增加,C:N在叶和茎中下降,C:P及N:P在叶、茎和粗根中增加,在细根中下降.各器官间C含量呈显著正相关,而各器官间N与P相关性均不显著.土壤含水量与各器官C含量,叶N含量,细根P含量及C:N,叶、茎和粗根C:P及N:P呈显著负相关,而与细根N含量,叶、茎和粗根P含量,细根C:P及N:P呈显著正相关.因此,干旱胁迫影响榆树幼苗对N、P的吸收及向上运输,幼苗生长主要受N限制;随着干旱胁迫的加剧,叶、茎和粗根生长受P限制作用增强.     

持续干旱下沙地樟子松幼苗C、N、P化学计量变化规律

为明确沙地樟子松幼苗在干旱胁迫过程中C、N和P化学计量的变化规律及分配特征,通过盆栽试验,对2年生沙地樟子松幼苗进行自然干旱处理,当土壤含水量下降到田间持水量的60%、40%、30%和20%时,测定各器官(当年生叶、一年生叶、茎、粗根和细根)的C、N和P含量。结果表明:持续干旱过程中,沙地樟子松幼苗N、P含量及C∶P和N∶P变异系数在粗根中最大,C含量变异系数在细根中最大; C、P含量及C∶P变异系数在一年生叶中最小,N含量和C∶N变异系数在当年生叶中最小,N∶P变异系数在茎中最小。随着田间持水量下降,C含量在当年生叶中先下降再上升后下降,在一年生叶、茎和粗根中先升高后降低,在细根中先下降后上升; N含量在当年生叶中先下降后上升,在一年生叶、茎和粗根中下降,在细根中先降低再升高后降低; P含量在当年生叶中上升,在一年生叶、茎、粗根和细根中先下降后上升; C∶N在一年生叶、茎、粗根和细根中增加,C∶P在当年生叶中下降,各器官N∶P均降低。相同元素在不同器官间紧密相关,而不同元素间相关性较差。因此,随着干旱加剧,沙地樟子松幼苗生长受N限制逐渐增强,N利用效率提高,各元素在叶和茎中稳定性高于粗根和细根。     

Effects of experimental warming on growth,biomass allocation,and needle chemistry of <Emphasis Type="Italic">Abies faxoniana</Emphasis> in even-aged monospecific stands

The response and adaption mechanisms of seedlings under long-term warming have remained largely unknown. In this study, we investigated the effects of warming for 6 years on growth, and needle carbon, nitrogen, chlorophyll, and carbohydrate levels in a coniferous tree species, Abies faxoniana. Seedlings were grown in even-aged monospecific stands under ambient and warming (ambient +2.2°C) temperature in climate control chambers. Warming caused statistically significant increases in the specific leaf area, leaf area ratio, root biomass, leaf biomass, branch biomass, stem biomass, and total mass of the seedlings, and reduced the root/shoot ratio. Warming also increased total chlorophyll concentrations, specific chlorophyll pigments, and Chlorophyll a/b ratios in both studied needle age classes. In addition, C/N ratios of current-year and 1-year-old needles increased by warming. In contrast, warming decreased the levels of N, sugar, cellulose, and starch in needles, while warming had no effect on the height, stem diameter, needle mass ratio, root mass ratio, and root/needle ratio. We conclude that warming increases branch growth and changes needle chemistry, which enhances the light capture potential of seedlings.     

Effects of Drought and Warming on Biomass, Nutrient Allocation, and Oxidative Stress in Abies fabri in Eastern Tibetan Plateau

Abies fabri (Mast.) Craib is an endemic and dominant species in typical subalpine dark coniferous forests distributed in the eastern Tibetan Plateau. To assess how A. fabri may respond and adapt to future climate changes, we investigated the effects of drought and warming on the growth, resource allocation in biomass, membrane stability, and oxidative stress of the seedlings over two growing seasons. Drought (11.4 % average reduction in soil moisture) was created by excluding natural precipitation with a plastic roof and warming was performed by an infrared heater above the plots. Drought increased root length, the root-to-shoot ratio, N concentration, and N/P ratio in all organs, and decreased seedling height and C/N ratio in all organs. Moreover, warming (2 °C) decreased seedling height, root length, total biomass, and N concentration in stems but increased the C/N ratio. Furthermore, the combination of drought and warming decreased seedling height and biomass in all organs, which further increased the N concentration and N/P ratio in all organs. A significant decrease in the membrane stability index and an increase in malondialdehyde, superoxide radical (O₂ ^?), and hydrogen peroxide (H₂O₂) were exactly matched with a dramatic decrease of total biomass under the combination of drought and warming treatment. Together these results implied that drought alone and warming alone were unfavorable for the early growth of A. fabri, and drought plus warming will intensify the opposite effect of drought alone or warming alone. Moreover, N will be a limited nutrient under extant and future climate changes.     

施肥对香樟幼苗生长及养分分配的影响

施肥是苗木培育的重要方式,香樟是乡土珍稀阔叶树种,苗木培育对乡土珍稀树种的保护、繁育、推广具有极其重要的作用,施肥对苗木的生长和发育具有重要的影响。因此,为了探讨香樟幼苗生长及植物体内养分分配对施肥的响应,该研究采用正交设计,设置了氮、磷、钾3因素3水平(N、P:0、3、6 g·株-1;K:0、2、4g·株-1),对盆栽香樟幼苗进行指数施肥。结果表明:(1)氮肥对香樟幼苗苗高、地径、生物量的影响最为显著,磷肥和钾肥的影响则较小;(2)氮素在香樟幼苗叶、茎、根中的分布状况主要受氮肥的影响,磷素在香樟幼苗叶、茎、根中的分布状况主要受氮肥和磷肥的影响,钾素在香樟幼苗叶、茎、根中的分布状况主要受钾肥的影响;(3)香樟幼苗的苗高生长与叶片氮含量、叶片磷含量呈显著正相关(P0.05),地径生长与茎氮含量呈显著正相关(P0.05),叶生物量与叶片氮含量、叶片磷含量呈显著正相关(P0.05),茎生物量与叶片磷含量呈显著正相关(P0.05);(4)综合分析得出,对香樟幼苗苗高、地径生长,以及枝叶生物量积累最具促进作用的施肥水平为氮肥(6 g·株-1)、磷肥(6 g·株-1)、钾肥(4 g·株-1)。     

川西北高寒草地3种主要植物的生长及物质分配对温度升高的响应

在野外自然条件下采用开顶式生长室模拟增温的方法, 研究了增温对川西北高寒草地3种主要植物(单子叶草本植物垂穗披碱草(Elymus nutans)和双子叶草本植物尼泊尔酸模(Rumex acetosa)和鹅绒委陵菜(Potentilla anserina))的生长及物质分配的影响。研究结果表明, 增温对3种植物的生长产生了显著影响, 垂穗披碱草和尼泊尔酸模的比叶面积和生物量积累在增温后显著增加, 而鹅绒委陵菜在增温后显著减少。在各组分中, 增温处理使尼泊尔酸模的叶生物量显著增加, 根生物量却显著下降, 而鹅绒委陵菜叶和茎的生物量在增温后显著减少, 根生物量却显著增加。增温对尼泊尔酸模各组分的养分含量产生了显著影响, 其中, 根部碳含量在增温后显著增加, 而氮含量在增温后显著减少。增温对尼泊尔酸模和鹅绒委陵菜的生物量在各组分中的分配产生了显著影响, 增温显著增加了尼泊尔酸模的叶重比(LMR)、根重比(RMR)和地下生物量/地上生物量(R/S), 而茎重比(SMR)在增温后却显著降低; 增温显著增加了鹅绒委陵菜的RMR和R/S, 而SMR和LMR在增温后却显著降低。增温对尼泊尔酸模和鹅绒委陵菜各组分中的碳、氮分配产生了显著影响, 增温显著增加了碳、氮在尼泊尔酸模叶片的分配比例, 并且使尼泊尔酸模根部的碳分配比例也显著增加, 而茎部的碳、氮分配比例却显著减少; 增温显著减少了碳在鹅绒委陵菜叶片的分配比例, 而根部的碳、氮分配比例却显著增加。     

Temperature-Induced Change in the Water Relations of Abies amabilis (Dougl.) Forbes

Water conductance through Abies amabilis seedlings was measured while the roots were exposed to temperatures from 15 to 0.25°C. Before conductance was measured, the seedlings were preconditioned for 3 months at either a high temperature (23°C) or a low temperature (3°C). For both groups of seedlings, conductance decreased as root temperature decreased. Conductance was lowest at 0.25°C. In addition, preconditioning at 3°C for 3 months significantly lowered conductance to water at all root temperatures. Under the same environmental conditions, seedlings preconditioned at 3°C had less than 25% of the transpirational water loss of seedlings preconditioned at high temperature. A decrease in leaf osmotic potential also resulted from low temperature preconditioning. In trees growing in the subalpine forest, which is the natural habitat of Abies amabilis, both decreased leaf conductance to water vapor and lower osmotic potentials were evident in winter. Since in winter the temperature of the soil in the subalpine zone remains less than 1°C for many months, lowered leaf conductance and decreased osmotic potentials appear to be mechanisms which aid in preventing desiccation damage.     

干旱区湿地芦苇各器官生态化学计量对土壤因子的响应

了解植物养分浓度及其化学计量对土壤因子的响应,对预测脆弱而敏感生态系统对环境变化的响应至关重要。以敦煌阳关湿地优势种芦苇(Phragmites australis)为对象,通过野外调查与实验分析,研究芦苇不同器官生态化学计量特征及其影响因素。结果表明:芦苇各器官C、P含量为叶>根>茎,N含量及N∶P为叶>茎>根,C∶N为根>茎>叶,C∶P则为茎>根>叶。叶、根C含量显著高于茎(P<0.05),叶、根C含量之间无显著差异(P>0.05),根、茎和叶N、P含量及C∶N、C∶P和N∶P差异显著(P<0.05);芦苇根N∶P<14,叶片N∶P>16,茎N∶P介于14~16;C含量在各器官之间均无显著相关性(P>0.05),根与茎、叶N含量之间呈极显著正相关(P<0.01),根与茎P含量呈极显著正相关(P<0.01),茎与叶N含量呈显著正相关(P<0.05);土壤盐分与芦苇根和茎N含量呈极显著正相关(P<0.01),土壤P含量与茎P含量呈极显著正相关(P<0.01),土壤有效P与根、茎N含量呈极显著正相关(P<0.01);土壤P是影响芦苇根、茎化学计量的主要因素,土壤盐分是影响叶片化学计量的主要因素,芦苇趋向提高各器官N含量来应对高盐、低P的土壤环境。     

Drought and warming induced changes in P and K concentration and accumulation in plant biomass and soil in a Mediterranean shrubland

A field experiment involving drought and warming manipulation was conducted over a 6-year period in a Mediterranean shrubland to simulate the climate conditions projected by IPCC models for the coming decades (20% decreased soil moisture and 1°C warming). We investigated P and K concentration and accumulation in the leaves and stems of the dominant species, and in soil. Drought decreased P concentration in Globularia alypum leaves (21%) and in Erica multiflora stems (30%) and decreased K concentration in the leaves of both species (20% and 29%, respectively). The general decrease of P and K concentration in drought plots was due to the reduction of soil water content, soil and root phosphatase activity and photosynthetic capacity that decreased plant uptake capacity. Warming increased P concentration in Erica multiflora leaves (42%), but decreased it in the stems and leaf litter of Erica multiflora and the leaf litter (33%) of Globularia alypum, thereby demonstrating that warming improved the P retranslocation and allocation from stem to leaves. These results correlate with the increase in photosynthetic capacity and growth of these two dominant shrub species in warming plots. Drought and warming had no significant effects on biomass P accumulation in the period 1999–2005, but drought increased K accumulation in aboveground biomass (10 kg ha⁻¹) in Globularia alypum due to the increase in K concentration in stems. The stoichiometric changes produced by the different responses of the nutrients led to changes in the P/K concentration ratio in Erica multiflora leaves, stems and litter, and in Globularia alypum stems and litter. This may have implications for the nutritional value of these plant species and plant–herbivore relationships. The effects of climate change on P and K concentrations and contents in Mediterranean ecosystems will differ depending on whether the main component of change is drought or warming.     

氮磷添加对巨桉幼苗生物量分配和C:N:P化学计量特征的影响

巨桉(Eucalyptus grandis)是一种优良的速生用材树种, 了解氮(N)和磷(P)对巨桉生长、养分限制、化学计量特征的影响对于科学合理施肥具有重要意义。该实验以巨桉无性系组培苗为研究对象, 通过在酸性紫色土中设置不同施N或施P梯度, 研究巨桉幼苗各器官(根、茎、叶)生物量及碳(C)、N、P的分配和化学计量特征以及巨桉生长的养分限制状况。结果表明: 施N处理对巨桉根茎叶及总生物量的影响极显著, 增加了地上部分的生物量比例而显著降低了根系的生物量比例; 施P对巨桉幼苗总生物量影响不显著, 但显著提高了根的生物量分配比例, 对茎和叶的生物量分配没有显著影响。施N或施P显著改变了巨桉幼苗的N、P含量和化学计量比, 同时也显著影响了土壤与植物N:P的关系。施N可以促使酸性紫色土条件下巨桉对N的吸收而抑制对P的吸收, 施P则促进巨桉幼苗对P的吸收。施N对巨桉幼苗根茎叶的C、N、P分配特征有极显著影响, 而施P对巨桉幼苗根茎叶的C、N、P分配没有显著影响。施N极显著降低了巨桉幼苗N的利用率, 显著提高了P的利用率, 而施P处理极显著降低了巨桉幼苗P的利用率。从巨桉生物量沿施肥梯度和N:P的变化规律可以判断, 当叶片N:P < 15时, 巨桉的生长主要受到N的限制作用。施N可以显著地提高根茎叶的N:P比值, 缓解巨桉缺N的现象, 施P则进一步加剧了N元素的缺乏。