Atmospheric nitrogen deposition affects forest plant and soil system carbon:nitrogen:phosphorus stoichiometric flexibility:A meta-analysis

Background:Nitrogen(N)deposition affects forest stoichiometric flexibility through changing soil nutrient availability to influence plant uptake.However,the effect of N deposition on the flexibility of carbon(C),N,and phosphorus(P)in forest plant-soil-microbe systems remains unclear.Methods:We conducted a meta-analysis based on 751 pairs of observations to evaluate the responses of plant,soil and microbial biomass C,N and P nutrients and stoichiometry to N addition in different N intensity(050,50–100,>100 kg·ha^(-1)·year^(-1)of N),duration(0–5,>5 year),method(understory,canopy),and matter(ammonium N,nitrate N,organic N,mixed N).Results:N addition significantly increased plant N:P(leaf:14.98%,root:13.29%),plant C:P(leaf:6.8%,root:25.44%),soil N:P(13.94%),soil C:P(10.86%),microbial biomass N:P(23.58%),microbial biomass C:P(12.62%),but reduced plant C:N(leaf:6.49%,root:9.02%).Furthermore,plant C:N:P stoichiometry changed significantly under short-term N inputs,while soil and microorganisms changed drastically under high N addition.Canopy N addition primarily affected plant C:N:P stoichiometry through altering plant N content,while understory N inputs altered more by influencing soil C and P content.Organic N significantly influenced plant and soil C:N and C:P,while ammonia N changed plant N:P.Plant C:P and soil C:N were strongly correlated with mean annual precipitation(MAT),and the C:N:P stoichiometric flexibility in soil and plant under N addition connected with soil depth.Besides,N addition decoupled the correlations between soil microorganisms and the plant.Conclusions:N addition significantly increased the C:P and N:P in soil,plant,and microbial biomass,reducing plant C:N,and aggravated forest P limitations.Significantly,these impacts were contingent on climate types,soil layers,and N input forms.The findings enhance our comprehension of the plant-soil system nutrient cycling mechanisms in forest ecosystems and plant strategy responses to N deposition.

天坑森林植物叶-凋落物-土壤C、N、P生态化学计量特征

为探究广西乐业大石围天坑森林群落的C、N、P养分循环特征,比较了天坑内外森林群落的植物叶片-凋落物-土壤C、N、P含量及其化学计量比,采用相关性分析和冗余分析等统计方法研究其内在联系和相互影响。结果表明,与天坑外部森林相比,天坑内部森林植物叶片和凋落物呈现出C低N、P高,土壤为C、N低P高的格局。植物叶片C:N、C:P与凋落物C、N:P显著正相关,植物叶片C与土壤P显著负相关;天坑外部森林的植物叶片N、N:P与土壤N:P显著负相关,植物叶片C:N与土壤C、C:N显著正相关,说明天坑森林内部凋落物的C、P养分可能主要来源于植物叶片,而天坑外部森林的植物叶片C、N主要来自土壤。土壤C:N:P对植物叶、凋落物的C:N:P变化的解释率分别为90.7%和50.6%,其中土壤P对植物叶和凋落物的C:N:P计量特征变化的解释度最高,坑内生境植物对P含量变化更为敏感、坑外植物对于N含量变化更为敏感,表明天坑内部森林可能是P素受限位点、天坑外部森林是N素受限位点。喀斯特天坑内部森林和外部森林植物叶-凋落物-土壤的C:N:P的差异和联系,体现了天坑内外森林群落的养分循环特征和植物群落的适应性。

水曲柳叶片功能性状及C、N、P化学计量对海拔的响应

【目的】水曲柳是小陇山主要珍贵的用材树种,探讨其叶片性状对小生境变化的适应性,可为深入研究影响该树种的主要环境因子提供理论基础。【方法】以黑河保护区天然水曲柳为研究对象,分析4个海拔梯度(1268,1529,1741,1926 m)间14种叶片功能性状和叶片营养元素含量的差异显著性及其相关性。【结果】(1)随海拔升高,叶片厚度、干物质含量和叶绿素含量逐渐增大,并分别在海拔1741 m、1926 m、1741 m处达到最大,比叶面积、最大净光合速率、蒸腾速率、叶C和N含量则逐渐减少,除叶C含量外均在海拔1268 m达到最大。叶面积、气孔导度和叶C∶N随着海拔升高呈先增后降的趋势,胞间CO_(2)浓度、C∶P和N∶P呈先降后升的趋势。(2)海拔平均每上升200 m,叶片功能性状和C∶N平均增加1.13%~30.72%,比叶面积、最大净光合速率和C、N含量减小2.22%~15.75%。(3)各海拔叶N∶P为4.36~6.89,与最大净光合速率呈极显著正相关。最大净光合速率与比叶面积、C和N含量、C∶P和N∶P呈极显著正相关,与叶片厚度、干物质含量和叶绿素含量呈极显著负相关,比叶面积与干物质含量呈极显著负相关,与C和N含量和C∶P呈极显著正相关。【结论】海拔显著影响水曲柳叶片功能性状及元素含量,海拔1700 m以下有利于叶的发育和养分的积累。

Ecological stoichiometry and biomass response of Agropyron michnoi Roshev.under simulated N deposition in a sandy grassland,China

Sandy grassland in northern China is a fragile ecosystem with poor soil fertility.Exploring how plant species regulate growth and nutrient absorption under the background of nitrogen(N)deposition is crucial for the management of the sandy grassland ecosystem.We carried out a field experiment with six N levels in the Hulunbuir Sandy Land of China from 2014 to 2016 and explored the Agropyron michnoi Roshev.responses of both aboveground and belowground biomasses and carbon(C),N and phosphorus(P)concentrations in the plant tissues and soil.With increasing N addition,both aboveground and belowground biomasses and C,N and P concentrations in the plant tissues increased and exhibited a single-peak curve.C:N and C:P ratios of the plant tissues first decreased but then increased,while the trend for N:P ratio was opposite.The peak values of aboveground biomass,belowground biomass and C concentration in the plant tissues occurred at the level of 20 g N/(m2•a),while those of N and P concentrations in the plant tissues occurred at the level of 15 g N/(m2•a).The maximum growth percentages of aboveground and belowground biomasses were 324.2%and 75.9%,respectively,and the root to shoot ratio(RSR)decreased with the addition of N.N and P concentrations in the plant tissues were ranked in the order of leaves>roots>stems,while C concentration was ranked as roots>leaves>stems.The increase in N concentration in the plant tissues was the largest(from 34%to 162%),followed by the increase in P(from 10%to 33%)and C(from 8%to 24%)concentrations.The aboveground biomass was positively and linearly correlated with leaf C,N and P,and soil C and N concentrations,while the belowground biomass was positively and linearly correlated with leaf N and soil C concentrations.These results showed that the accumulation of N and P in the leaves caused the increase in the aboveground biomass,while the accumulation of leaf N resulted in the increase in the belowground biomass.N deposition can alter the allocation of C,N and P stoichiometry in the plant tissues and has a high potential for increasing plant biomass,which is conducive to the restoration of sandy grassland.

青海东部农区引进燕麦品种各器官C、N、P生态化学计量学特征变化研究

以4个引种燕麦(Avena sativa)为典型代表,对其不同生育时期根、茎、叶中的C、N、P含量及其化学计量学特征进行测定,探讨不同生育时期燕麦C、N、P元素含量及其化学计量比的变化规律,为燕麦饲草的科学收获提供理论依据。结果表明:燕麦全株C、N、P含量分别为322.30~333.97、17.42~75.62、2.74~5.42 mg·g^(-1),燕麦根C、N、P含量分别为298.42~317.92、11.47~73.71、2.82~3.42 mg·g^(-1),燕麦茎C、N、P含量分别为311.25~338.86、10.15~75.16、2.44~5.06 mg·g^(-1),燕麦叶C、N、P含量分别为330.80~372.47、30.64~113.80、2.59~8.65 mg·g^(-1);各器官间C、N、P含量表现为叶>茎>根。此外,燕麦各器官C、N、P含量的积累过程具有一定季节特征,C含量积累过程受生育时期影响较小,表现出较强的稳定性;而N和P含量的积累过程受生育时期影响较大,其在拔节期~抽穗期均高于开花期~乳熟期。燕麦各器官C∶N、C∶P和N∶P分别为4.42~24.44、70.72~124.56和6.56~17.28,其中C∶N、C∶P在开花期~乳熟期均高于拔节期~抽穗期;N∶P则规律相反。

Degradation induces changes in the soil C:N:P stoichiometry of alpine steppe on the Tibetan Plateau

Due to the Tibetan Plateau’s unique high altitude and low temperature climate conditions,the region’s alpine steppe ecosystem is highly fragile and is suffering from severe degradation under the stress of increasing population,overgrazing,and climate change.The soil stoichiometry,a crucial part of ecological stoichiometry,provides a fundamental approach for understanding ecosystem processes by examining the relative proportions and balance of the three elements.Understanding the impact of degradation on the soil stoichiometry is vital for conservation and management in the alpine steppe on the Tibetan Plateau.This study aims to examine the response of soil stoichiometry to degradation and explore the underlying biotic and abiotic mechanisms in the alpine steppe.We conducted a field survey in a sequent degraded alpine steppe with seven levels inNorthern Tibet.The plant species,aboveground biomass,and physical and chemical soil properties such as the moisture content,temperature,pH,compactness,total carbon(C),total nitrogen(N),and total phosphorus(P)were measured and recorded.The results showed that the contents of soil C/N,C/P,and N/P consistently decreased along intensifying degradation gradients.Using regression analysis and a structural equation model(SEM),we found that the C/N,C/P,and N/P ratios were positively affected by the soil compactness,soil moisture content and species richness of graminoids but negatively affected by soil pH and the proportion of aboveground biomass of forbs.The soil temperature had a negative effect on the C/N ratio but showed positive effect on the C/P and N/P ratios.The current study shows that degradation-induced changes in abiotic and biotic conditions such as soil warming and drying,which accelerated the soil organic carbon mineralization,as well as the increase in the proportion of forbs,whichwere difficult to decompose and input less organic carbon into soil,resulted in the decreases in soil C/N,C/P,and N/P contents to a great extent.Our results provide a sound basis for sustainable conservation and management of the alpine steppe.

Elevated CO_(2) increases shoot growth but not root growth and C:N:P stoichiometry of Suaeda aralocaspica plants

The purpose of the current study was to investigate the eco-physiological responses,in terms of growth and C:N:P stoichiometry of plants cultured from dimorphic seeds of a single-cell C4 annual Suaeda aralocaspica(Bunge)Freitag and Schütze under elevated CO_(2).A climatic chamber experiment was conducted to examine the effects of ambient(720μg/L)and CO_(2)-enriched(1440μg/L)treatments on these responses in S.aralocaspica at vegetative and reproductive stages in 2012.Result showed that elevated CO_(2) significantly increased shoot dry weight,but decreased N:P ratio at both growth stages.Plants grown from dimorphic seeds did not exhibit significant differences in growth and C:N:P stoichiometric characteristics.The transition from vegetation to reproductive stage significantly increased shoot:root ratio,N and P contents,but decreased C:N,C:P and N:P ratios,and did not affect shoot dry weight.Moreover,our results indicate that the changes in N:P and C:N ratios between ambient and elevated CO_(2) are mainly caused by the decrease of N content under elevated CO_(2).These results provide an insight into nutritional metabolism of single-cell C4 plants under climate change.

Patterns and driving factors of leaf C,N,and P stoichiometry in two forest types with different stand ages in a mid-subtropical zone

Background:Carbon(C),nitrogen(N),and phosphorus(P)stoichiometry is a key indicator of nutrient utilization in plants,and C/N/P ratios are related to the life histories and adaptation strategies of tree species.However,no consensus has been reached on how leaf stoichiometric characteristics are affected by forest type and stand ages.The relationships between leaf stoichiometry and geographical,meteorological,and soil factors also remain poorly understood.Methods:Leaf and soil were sampled from forest stands of different age groups(young,middle-aged,near-mature,and mature)in two forest types(Chinese fir(Cunninghamia lanceolata)forests and evergreen broadleaved forests).The relationships between leaf C,N,and P stoichiometric parameters and geographical,meteorological,and soil factors were analysed by using redundancy analysis(RDA)and stepwise linear regression analysis.Results:Leaf C concentrations peaked in the near-mature stands with increasing age irrespective of forest type.Leaf N and P concentrations fluctuated with a rising trend in Chinese fir forests,while decreased first and increased later from young to mature phases in natural evergreen broadleaved forests.Chinese fir forests were primarily limited by N and P,while natural evergreen broadleaved forests were more susceptible to P limitation.Leaf C,N,and P stoichiometric characteristics in Chinese fir forests were mainly affected by the soil total P concentration(SP),longitude(LNG),growing season precipitation(GSP)and mean temperature in July(JUT).The leaf C concentration was mainly affected by GSP and JUT;leaf N and P concentrations were both positively correlated with LNG;and leaf P was positively correlated with SP.In evergreen broadleaved forests,however,leaf stoichiometric parameters displayed significant correlations with latitude(LAT)and mean annual precipitation(MAP).Conclusions:Leaf stoichiometry differed among forest stands of different age groups and forest types.Leaf C,N,and P stoichiometry was primarily explained by the combinations of SP,LNG,GSP and JUT in Chinese fir forests.LAT and MAP were the main controlling factors affecting the variations in the leaf C,N,and P status in natural evergreen broadleaved forests,which supports the temperature-plant physiological hypothesis.These findings improve the understanding of the distribution patterns and driving mechanisms of leaf stoichiometry linked with stand age and forest type.

Effects of arbuscular mycorrhizal fungi on carbon assimilation and ecological stoichiometry of maize under combined abiotic stresses

Arbuscular mycorrhizal fungi(AMF)enhance plant tolerance to abiotic stresses like salinity and improve crop yield.However,their effects are variable,and the underlying cause of such variation remains largely unknown.This study aimed to assess how drought modifed the effect of AMF on plant resistance to high calcium-saline stress.A pot experiment was performed to examine how AMF inoculation affects the growth,photosynthetic activity,nutrient uptake and carbon(C),nitrogen(N)and phosphorus(P)stoichiometric ratio(C:N:P)of maize under high calcium stress and contrasting water conditions.The results showed that high calcium stress signifcantly reduced mycorrhizal colonization,biomass accumulation,C assimilation rate and C:N stoichiometric ratio in plant tissues.Besides,the adverse effects of calcium stress on photosynthesis were exacerbated under drought.AMF inoculation profoundly alleviated such reductions under drought and saline stress.However,it barely affected maize performance when subjected to calcium stress under well-watered conditions.Moreover,watering changed AMF impact on nutrient allocation in plant tissues.Under well-watered conditions,AMF stimulated P accumulation in roots and plant growth,but did not induce leaf P accumulation proportional to C and N,resulting in increased leaf C:P and N:P ratios under high calcium stress.In contrast,AMF decreased N content and the N:P ratio in leaves under drought.Overall,AMF inoculation improved maize resistance to calcium-salt stress through enhanced photosynthesis and modulation of nutrient stoichiometry,particularly under water defcit conditions.These results highlighted the regulatory role of AMF in carbon assimilation and nutrient homeostasis under compound stresses,and provide signifcant guidance on the improvement of crop yield in saline and arid regions.

典型喀斯特峰丛洼地植被群落凋落物C∶N∶P生态化学计量特征

为了解典型喀斯特峰丛洼地植被群落凋落物养分空间分异以及其生态化学计量特征,分析了4个不同演替阶段植被凋落物现存量、C、N、P含量及C、N、P元素比值关系在不同坡位间的差异。结果表明:(1)不同演替阶段群落凋落物现存量和C、N、P含量、N∶P值随植被正向演替而升高;C∶N值和C∶P值随植被正向演替而下降。(2)凋落物C含量、C∶N值、C∶P值和N∶P值在不同坡位表现为上坡位较高、下坡位较低;P含量的变化规律与之相反,N含量则没呈现很明显的规律性(P<0.05)。典范对应分析(CCA)结果表明演替阶段和坡位对凋落物积累、养分分布和存储影响最大,坡度、坡向和裸岩率也有较大影响。(3)N∶P值是制约凋落物分解和养分循环的重要因素。凋落物在P素较低的情况下具有较高的N及木质素含量(即较高的N∶P值),分解速率较低,较低的N∶P值使凋落物更易分解。N素在3个坡位的不显著差异以及P素的显著差异反映了P含量波动对喀斯特峰丛洼地植被凋落物N∶P值和分解速率变化的影响。推测下坡位及幼龄林群落由于具有较低的N∶P值,其凋落物分解速率相对较快,养分的存储量较少。因此,上坡位、成熟林群落的凋落物有利于积累养分。

施肥对羊草割草地植物群落和土壤C:N:P生态化学计量学特征的影响

以呼伦贝尔羊草(Leymus chinensis)草甸天然割草场为研究对象,通过设置不同种类肥料和不同施肥量处理,探讨植物群落生产力、植物群落和土壤C:N:P生态化学计量学特征,试图筛选出适合该地区草地生长的施肥种类与施肥量的最优组合。结果表明:随着施肥水平的增加,2014年群落地上生物量呈上升趋势,H3(尿素10.5 g·m^(-2)+过磷酸钙5.1 g·m^(-2))的生物量最高(505.8 g·m^(-2));2015年群落地上生物量先增加后减少,施肥水平H2(尿素7.0 g·m^(-2)+过磷酸钙3.4 g·m^(-2))生物量最高(264 g·m^(-2))。2014年和2015年不同施肥处理下植物群落C、N和P含量差异不显著。2014年不同处理间植物群落C:N差异显著,H3施肥水平的C:N(29.28)显著高于其他水平(P<0.05),而2015年C:N随着施肥水平的增加而增加;与C:N变化趋势完全相反,2014年、2015年群落的C:P和N:P均随施肥水平增加而减少。2014年与2015年不同处理下土壤全C、全N和全P中,除2014年0~10 cm土层H2和H3的全N、H1的全P显著高于其他处理(P<0.05),其他指标在不同处理间差异均不显著。2014年3层土壤的C:N、C:P和N:P受施肥量的影响相对较小,变化范围分别为18.31~19.42、64.06~102.51、3.38~5.19。2015年3层土壤的C:N、C:P和N:P变化范围为11.33~12.51、25.59~53.49、2.17~4.41。对比2年比值的变化,2015年C:P和N:P较2014分别下降了47.8%~59.7%和15.0%~35.8%。研究结果表明:从植物群落和土壤的化学计量比角度来看,N可能是本地区限制植物生长的一个主要因素,P处于相对平衡的状态,在未来的N、P混施管理中,需降低或不添加磷肥,适量添加N素,才能使群落呈现适中的化学计量比。

短期增温对贡嘎山峨眉冷杉幼苗生长及其CNP化学计量学特征的影响

2009年5月至10月,在中国科学院贡嘎山高山森林生态系统观测站附近,采用红外灯加热人工模拟气候变暖研究了增温对峨眉冷杉(Abies fabiri(Mast)Craib)幼苗生长和养分及其化学计量特征的影响。由于红外灯的增温作用,在幼苗的整个生长季节,增温样地地表下5、10、20 cm处土温平均高于对照样地5.04、4.81、4.35℃,而土壤含水量则分别降低了7.03%、6.10%、6.40%;地表20 cm处空气温度相比对照样地上升了1.12℃,而空气相对湿度则降低了6.30%。除茎重比外,增温处理降低了峨眉冷杉幼苗的根长、基径、株高、总生物量、根重比、叶重比、根冠比和比叶面积。经方差分析发现,增温处理后幼苗根、茎和叶的C平均含量与对照差异性均不显著(P>0.05),其中除茎的提高了2.76%外,根和叶分别降低了7.15%和2.29%;N平均含量除茎显著降低之外(P<0.05),根、叶分别提高了9.78%和5.70%;幼苗根、茎、叶的P平均含量均低于对照11.97%、10.69%和2.99%,并且根和茎与对照存在显著性差异(P<0.05)。增温处理后幼苗根、茎、叶各器官的C∶N、C∶P、N∶P与对照均不存在显著性差异(P>0.05),其中C∶P均大于对照,而C∶N和N∶P与对照相比,均有不同程度的减小;C∶N、N∶P和C∶P的平均值(±标准差)大小顺序依次为茎(92.59±4.92)>根(61.89±1.65)>叶(60.81±3.23)、叶(4.99±0.22)>根(4.44±0.58)>茎(3.64±0.10)和茎(336.35±8.70)>叶(302.85±4.49)>根(274.86±5.27)。实验结果表明:增温对幼苗生长和生物量积累具有明显的限制作用,对叶片生长的阻碍作用尤为突出;增温改变了幼苗根茎叶的CNP含量及其化学计量比格局;在养分供应上,增温和对照处理下幼苗生长均受N素限制。

去除顶端优势对菊芋器官C、N、P化学计量特征的影响

以不同时期顶端优势去除处理的菊芋为研究对象,通过测定根、茎、叶、花和块茎等器官C、N、P含量,计算C∶N、C∶P和N∶P比值,探讨顶端优势去除对菊芋各器官C、N、P化学计量特征的影响规律。结果表明:各器官之间C含量高低顺序没有因去顶而改变,氮和磷含量高低顺序因去顶而表现出不同的大小关系;顶端优势去除提高了茎秆、块茎和分枝的C含量,除最后一次顶端优势去除提高了叶片C含量,其它顶端优势去除时间均降低了叶片含量;顶端优势去除降低了根系、茎秆和块茎N含量,提高了分枝和花的含N量;顶端优势去除提高了叶片和块茎的含P量;C∶N范围为24.15—153.75、C∶P范围为118.87—2265.72、N∶P范围为2.46—24.05,N∶P平均值为10.67,说明菊芋生长主要受N元素的限制。

不同生境条件下滨海芦苇湿地C、N、P化学计量特征

为阐明不同生境对黄河三角洲滨海芦苇湿地土壤和植物碳(C)氮(N)磷(P)含量及生态化学计量特征的影响,选取新生湿地和退耕湿地两种湿地类型为研究对象,对土壤和植物体C、N、P含量及其化学计量特征进行研究。研究表明:1)退耕芦苇湿地土壤TC、TN的含量明显增加,TP的含量变化不大。2)新生湿地和退耕湿地土壤R_(C、N、P)分别为42.6:1.6:1、71.2:2.0:1,R_(NP)低于全球平均水平(13.1)和我国平均水平(5.2),土壤表现为N限制。新生湿地土壤剖面中,R_(CN)和R_(CP)变化剧烈;R_(NP)值随深度的增加而减小;退耕湿地土壤R_(C、N、P)值规律性较好,R_(CN)随深度的增加而变大,R_(CP)和R_(NP)值随深度的增加而减小。3)新生湿地和退耕湿地中芦苇整株R_(CN)、R_(CP)和R_(NP)平均值分别为78.2、1753、22.4;67.0、1539、23.0。开垦活动可以降低芦苇植物体R_(CN)和R_(CP)值,但由于芦苇植物体本身对R_(NP)的约束性较高,对R_(NP)值的影响不大,芦苇植株R_(NP)约为23。以上结论可以为黄河三角洲国家级自然保护区正在进行的湿地保护与恢复工作提供借鉴和参考。

贵州石灰岩和砂岩地区C_4和C_3植物营养元素的化学计量对N/P比值波动的影响

陆地生态系统植物的生长受到营养元素氮(N)和磷(P)的可利用性的限制。已有的证据表明营养元素的相对丰度将控制生态系统的营养元素循环和能量流动的速度。文章提出如下假设:为了适应环境的变化,植物具有可伸缩性地调整营养元素含量的能力,也就是营养元素化学计量比值变化的能力,植物N/P比值波动的影响不仅来源于N对P的相对可利用性的变化,也来源于其他营养元素化学计量的变化,尤其是与Ca的化学计量的变化。为了验证上述假设,本研究利用3种C4植物和11种C3植物,研究了植物N/P化学计量比值的波动随N与Ca和P与Ca化学计量的变化模式:对C4植物来说,N/P比值的波动主要受生物量P与Ca化学计量变化的影响;而对C3植物来说,则同时受N与Ca和P与Ca化学计量变化的控制,它们之间的相对控制能力的大小将决定植物N/P比值波动的变化梯度,C4植物和C3植物的N/P比值的波动都要受土壤pH值的影响。本研究对了解物种丰度和N对P的相对可利用性、N与Ca,以及P与Ca的化学计量之间关系具有重要意义。

高寒草甸冷季放牧对凋落物分解及C、N、P化学计量特征的影响

为深入理解放牧对青藏高原高寒草地冷季牧场凋落物分解及C、N、P化学计量特征的影响,本研究分析了不同放牧强度下冷季牧场凋落物现存量及C、N和P化学计量特征动态。结果表明,凋落物现存量随着放牧强度的增加而减少,轻度(22.50个羊单位·hm^(-2))、中度(26.25个羊单位·hm^(-2))、重度(32.04个羊单位·hm^(-2))放牧草地凋落物现存量依次为45.72~125.52、17.32~56.6、8.64~30.96g·m^(-2)。放牧季随时间推移各放牧强度下现存凋落物的C含量逐渐降低,同一时期现存凋落物C含量依次为轻度放牧>中度放牧>重度放牧。在休牧期,随时间推移,中度和重度放牧的凋落物C含量呈显著增加趋势。放牧期,凋落物N含量随时间推移呈下降趋势。放牧期,同一时期现存凋落物P含量均表现为重度放牧>中度放牧>轻度放牧;而休牧期,同一时期现存凋落物P含量均表现为轻度放牧>重度放牧>中度放牧。重度放牧下,草地现存凋落物C/N均在90以上,休牧初期(7月)草地现存凋落物C/P较高,均在1 000以上。综合得出,随着放牧强度的增加,凋落物损失率显著增大,N含量降低,C含量变化不显著,P出现富集。

不同满江红C、N、P生态化学计量学的季节变化

为了评价不同满江红的生态化学计量特征的差异,以8种不同满江红为对象,在网室土壤水培养条件下,研究季节变化对满江红产量,碳(C)、氮(N)、磷(P)含量及其化学计量比的影响。结果表明:随温度的增加,满江红的生物量产量呈先升高后降低趋势,在夏季达到最高。四季平均产量最高为闽育1号小叶萍4087,达244.25g·盆-1,第二为回交萍MH3-1,达240.43g·盆-1,第三为卡州萍3001,达232.14g·盆-1。满江红的C含量呈先降低再逐渐升高,C含量在春季达到最高,达44.40%;N、P含量表现为先升高再降低的趋势,在夏季达到最高,分别达4.50%和0.86%,综合C、N、P含量,卡州萍3001、细绿萍1001、墨西哥萍2002的C、N、P含量明显优于其他的满江红。满江红C∶N、C∶P和N∶P随温度变化呈先降低再升高趋势,夏季达最低。不同满江红在不同季节C∶N、C∶P和N∶P变化范围分别为7.93~18.20、41.05~225.18、5.16~23.90。本试验条件下,综合生物量产量、C、N、P含量,卡州萍3001的特性优于其他的满江红。

放牧对峰丛洼地植物-土壤C、N、P化学计量特征的影响

以西南典型岩溶峰丛洼地平果石漠化区为研究区,选取受放牧干扰和未受放牧干扰植被样地,开展放牧干扰对植物-土壤C、N、P元素生态化学计量学特征影响的研究。结果显示,(1)6种受放牧干扰样地土壤(0～20cm)的C、N、P含量均值分别为6.27%、0.57%、0.088%;植物根、茎、叶和凋落物C、N、P含量均值分别为442.15g·kg^(-1)、8.33g·kg^(-1)、0.73g·kg^(-1)。放牧干扰下,植物和土壤C、N、P含量减少,变异系数增大,容易导致石漠化发生和恶化;(2)6种典型样地土壤C∶N、C∶P、N∶P均值分别为10.76、73.94、6.76;植物根、茎、叶和凋落物C∶N、C∶P、N∶P分别为53.62、669.50、12.53。与无放牧干扰样地相比较,受放牧干扰的样地植物和土壤C∶N、C∶P、N∶P化学计量比呈下降趋势,放牧干扰在一定范围内能提高土壤P的有效性,但当N∶P比值减少到一定程度时,植物的生长受N限制。(3)恢复样地的土壤-植被C、N、P及其比值都优于干扰样地,放牧干扰能在短时间内造成环境迅速退化和石漠化的发生和加剧。禁牧后土壤和植物养分能在短时间内得到修复和改善,尤其是草本饲料类植物经短时间自然恢复后得以恢复正常生长发育。(4)在岩溶峰丛洼地石漠化区,土壤和植物的C、N、P、C∶N、C∶P、N∶P关系密切,相互之间具有促进或抑制的作用,共同影响植物的生长发育和石漠化演变方向。

黄土丘陵区燕沟流域典型植物叶片C、N、P化学计量特征季节变化

以黄土丘陵区燕沟流域为例,分析了流域8种典型植物叶片C、N、P化学计量特征的季节变化。结果发现,8种植物叶片C含量分布范围在370.2—566.9 mg/g,N含量在9.2—39.0 mg/g,P含量在0.81—2.35 mg/g,C∶N在10.5—52.9,C∶P在186.8—667.5,N∶P在5.7—23.0。叶片平均C、C∶N和C∶P在5月小于7月和9月(P<0.05),而在7月和9月差异不显著;N在5月大于7月和9月(P<0.05),7月和9月差异不显著;P在7月小于5月和9月(P<0.05),5月和9月差异不显著;N∶P在9月明显小于5月和7月(P<0.05),5月和7月差异不显著。叶片C含量受季节因素影响显著,而在物种间差异不显著;叶片N、P、C∶N、C∶P、N∶P受物种和季节因素影响均显著。因此,8种植物中沙棘、黄刺梅和虎榛子采用防御性的生活史策略;刺槐、柠条和狼牙刺采用竞争性生活史策略,铁杆蒿和茭蒿的生活史策略介于上述二者之间;尽管叶片N∶P随生长季节发生明显变化,但研究区植物生长的限制性元素未随生长季节变化而改变。

安徽石台亚热带常绿阔叶林植物叶中C、N、P特征分析

以安徽石台亚热带常绿阔叶林植物叶片为研究对象,分析了植物叶中C、N、P含量以及它们之间的化学计量关系,讨论了不同类型植物叶片的化学计量特征。结果显示：所研究的28种植物物种间差异明显,叶片中C含量为400.08-519.36 mg/g,N为5.15-15.39 mg/g,P为0.30-0.97 mg/g,m（C）∶m（N）范围为29.99-92.25、m（C）∶m（P）的范围为467.01-1 443.81、m（N）∶m（P）的范围为10.01-29.29,且N与P、m（C）∶m（N）值与m（C）∶m（P）值之间呈现显著的正相关关系,m（N）∶m（P）的变化主要由P含量决定。不同生活型植物m（C）∶m（N）值从大到小表现为灌木（59.68）〉乔木（51.56）〉草本和藤本植物（44.50）,草本和藤本植物与灌木之间m（C）∶m（N）差异显著;不同植物m（C）∶m（P）值从大到小表现为灌木（1 043.4）〉草本和藤本植物（818.78）〉乔木（808.35）,灌木与乔木、草本和藤本植物都存在显著差异。该地区灌木m（C）∶m（N）值和m（C）∶m（P）值均最高,说明灌木对N、P的利用效率最高。3种类型植物m（N）∶m（P）值均大于16,说明该地区常绿阔叶林主要受P限制。虽然植物受P限制,但其m（C）∶m（P）值含量较高,说明植物对其生长受限的元素利用效率会更高,这反映了植物对环境适应的一种对策。