青藏高原东缘主要针叶树种叶片碳氮磷化学计量分布格局及其驱动因素

理解植物叶片化学计量特征及其驱动因素对认识植物种群分布规律及预测植物对环境变化响应具有重要意义。该研究采集了青藏高原东缘针叶林84个样点共29种主要针叶树种叶片,探讨该区域常绿针叶树种叶片碳(C)、氮(N)、磷(P)化学计量特征和分布格局及其驱动因素。结果表明:(1)在科和属水平上,不同针叶树种叶片C、N含量和C:N差异显著;叶片N:P 14,表明该区域针叶树种主要受N限制。(2)叶片N、P含量在环境梯度上表现出一致的分布规律:均呈现出随纬度和海拔增加而显著降低,随年平均气温(MAT)和年降水量(MAP)增加而显著增加的趋势;而叶片C含量与纬度、海拔、MAT和MAP均未表现出显著相关性。(3)叶片C:N、C:P呈现出与N、P含量变化相反的分布格局:均随纬度和海拔增加而显著增加,随MAT和MAP增加而显著降低;而叶片N:P与海拔、MAT和MAP均无显著相关性。(4)进一步分析表明,叶片C、N、P含量及其化学计量比的主要驱动因素不尽相同。具体而言:土壤特性是叶片C含量和N:P变异的主要驱动因子,而叶片N、P含量和C:N、C:P的变异主要由气候因素决定。总之,该区域针叶树种叶片化学计量沿环境梯度的变异规律有力地支持了温度生物地球化学假说,在一定程度上丰富了对环境变化下植物叶片化学计量分布格局及其驱动机制的认识。     

中亚热带植被恢复阶段植物叶片、凋落物、土壤碳氮磷化学计量特征

为揭示植被恢复过程中生态系统的养分循环机制及植物的生存策略, 根据亚热带森林群落演替过程, 采用空间代替时间方法, 以湘中丘陵区地域相邻、环境条件基本一致的檵木(Loropetalum chinensis) +南烛(Vaccinium bracteatu) +杜鹃(Rhododendron mariesii)灌草丛(LVR)、檵木+杉木(Cunninghamia lanceolata) +白栎(Quercus fabri)灌木林(LCQ)、马尾松(Pinus massoniana) +柯(Lithocarpus glaber) +檵木针阔混交林(PLL)、柯+红淡比(Cleyera japonica) +青冈(Cyclobalanopsis Glauca)常绿阔叶林(LCC)作为一个恢复系列, 设置固定样地, 采集植物叶片、未分解层凋落物和0-30 cm土壤样品, 测定有机碳(C)、全氮(N)、全磷(P)含量及其化学计量比, 运用异速生长关系、养分利用效率和再吸收效率分析植物对环境变化的响应和养分利用策略。结果表明: (1)随着植被恢复, 叶片C:N、C:P、N:P显著下降, 而叶片C、N、P含量和土壤C、N含量、C:P、N:P显著增加, 其中LCC植物叶片C、N含量, 土壤C、N含量及其N:P, PLL植物叶片P含量, 土壤C:P显著高于其他3个恢复阶段, 各恢复阶段植物叶片N:P > 20, 植物生长受P限制; 凋落物C、N、P含量及其化学计量比波动较大。(2)凋落物与叶片、土壤的化学计量特征之间的相关关系较弱, 叶片与土壤的化学计量特征之间具有显著相关关系, 其中叶片C、N、P含量与土壤C、N含量、C:N (除叶片C、N含量外)、C:P、N:P呈显著正相关关系; 叶片C:N与土壤C、N含量、C:P、N:P, 叶片C:P与土壤C含量、C:N、C:P, 叶片N:P与土壤C:N呈显著负相关关系。(3)植被恢复过程中, 叶片N、P之间具有显著异速生长关系, 异速生长指数为1.45, 叶片N、P的利用效率下降, 对N、P的再吸收效率增加, LCC叶片N利用效率最低, PLL叶片P利用效率最低而N、P再吸收效率最高。(4)叶片N含量内稳态弱, 而P含量具有较高的内稳态, 在土壤低P限制下植物能保持P平衡。植被恢复显著影响叶片、凋落物、土壤C、N、P含量及其化学计量比, 叶片与土壤之间C、N、P含量及化学计量比呈显著相关关系, 植物通过降低养分利用效率和提高养分再吸收效率适应土壤养分的变化, 叶片-凋落物-土壤系统的N、P循环随着植被恢复逐渐达到“化学计量平衡”。     

中国毛竹林碳氮磷生态化学计量特征

碳(C)、氮(N)、磷(P)生态化学计量比是生态系统过程与功能的重要特征, 开展种群生态化学计量学研究可以细化植物种群化学计量学内容, 确定限制植物生长的元素类型, 同时为大尺度模型的发展提供数据基础。为阐明我国毛竹(Phyllostachys edulis)林C、N、P化学计量学特征, 通过对毛竹主要产区文献数据的搜集整理与分析, 探索我国毛竹林“植物-土壤-凋落物”系统C、N、P及C:N、C:P、N:P生态化学计量特征, 以及不同组分生态化学计量特征与经纬度之间的关系。结果表明: 1)我国毛竹林叶片C含量为478.30 mg·g^-1, N含量为22.20 mg·g^-1, P含量为1.90 mg·g^-1, C:N为26.80, C:P为299.60, N:P为14.40; 毛竹林0-20 cm土层C含量为21.53 mg·g^-1, N含量为1.66 mg·g^-1, P含量0.41 mg·g^-1, C:N为14.20, C:P为66.74, N:P为4.28; 毛竹凋落物C含量为438.49 mg·g^-1, N含量为13.39 mg·g^-1, P含量为0.86 mg·g^-1, C:N为22.53, C:P为665.67, N:P为22.55。2)毛竹林“植物-土壤-凋落物”系统中, C:N表现为: 叶片>凋落物>土壤, C:P和N:P均表现为: 凋落物>叶片>土壤, 叶片N、P再吸收率分别为39.68%和54.74%, 我国毛竹林生长发育总体上可能受到P限制或者N和P两种元素的双重限制。3)纬度梯度: 叶片N含量、N:P随纬度增加而增加, C:N随纬度增加而降低。经度梯度: 叶片N:P随经度增加而增加, P含量、C:N随经度增加而降低; 土壤C:N随经度增加而增加, N含量随经度增加而降低; 凋落物N含量随经度增加而降低。4)叶片N含量与年平均气温和年降水量均存在明显负相关关系, 但对温度的响应比降水更敏感, 叶片N含量与纬度呈正相关关系, 支持“温度-植物生理假说”, 反映了植物对自然环境的适应。     

呼伦贝尔草地植物群落与土壤化学计量学特征沿经度梯度变化

植物化学计量学特征在大尺度上主要受纬度和经度两个因素影响。纬度梯度上温度因子变化对植物化学计量特征的影响已有大量研究,但是关于经度梯度上降雨因子变化对植物化学计量特征影响的研究却较少。选取呼伦贝尔草原,研究经度梯度上植物化学计量特征和土壤养分指标的变化规律,从经度梯度和养分供给两方面分析植物群落化学计量特征的变化规律,研究结果如下:1)植物群落叶片C含量变化范围为440.76—452.72 mg/g,N含量变化范围为17.79—30.88 mg/g,P含量变化范围为1.31—1.71 mg/g;群落叶片C含量、C/N随经度升高显著增加;群落叶片N含量随经度升高显著下降;植物群落P含量也呈下降趋势,但是关系不显著;植物群落C、N和P元素总量随着经度升高而显著增加。2)0—10 cm土壤全碳、全氮、全磷、有机碳受降雨量变化和植物群落元素总量影响,随着经度梯度升高而增加;但土壤铵态氮、硝态氮在经度梯度上没有表现出规律性的变化趋势。3)土壤全碳、有机碳、全氮、全磷和速效磷与植物群落叶片C、N和P含量没有显著相关关系,但与植物群落C、N和P元素总量呈显著正相关关系。该区土壤有效磷含量(8.13 mg/kg)高于全球平均值(7.65 mg/kg),但植物群落叶片磷含量平均值(1.5 mg/g)低于全球平均值(1.77 mg/g)。通过研究结果推测:植物通过对气候条件的长期适应,群落水平C、N和P含量沿经度梯度形成一定的分布格局;降雨量影响植物群落元素积累的总量,从而与土壤养分含量呈显著正相关关系;植物叶片P含量低的原因并非是由于土壤中磷的供给不足所致,而是植物对环境长期适应形成的策略。     

贺兰山东麓不同植被类型叶片化学计量特征研究

为了探究贺兰山东麓地区不同植被类型植物叶片碳氮磷含量及其计量比特征与环境因子的关系。该研究于研究区沿海拔梯度设置了高山草甸、云杉纯林、山杨纯林、浅山灌丛和荒漠草原5个典型植被样地,测定了63种植物叶片碳、氮、磷含量和样地土壤养分特征,分析了植物叶片碳氮磷含量及其计量比特征与环境因子的关系。结果表明:(1)贺兰山东麓地区63种植物叶片平均C含量为520.46±62.08 mg·g-1,平均N含量为24.03±3.37 mg·g-1,平均P含量为1.69±0.51 mg·g-1;植物叶片N、P、C/N、C/P、N/P服从正态分布,而叶片C不符合正态分布,且叶片C/P和N/P较之C/N变异更大。(2)不同生活型植被叶片化学计量差异显著;叶片C、P含量乔木最高,叶片N含量草本最高;乔木植物叶片C/N最高,而N/P最低;叶片的C/P灌木最高。(3)植物叶片N含量、N/P和C/P均随海拔上升而增高,在海拔2073 m(山杨纯林处)显著降低,之后又呈显著增高趋势;而植物叶片P含量和C/N在山杨纯林处达到最高值随后呈显著下降趋势。(4)荒漠草原和浅山灌丛受到P限制,云杉纯林受到N限制,高山草甸可能受N、P的共同限制。虽然山杨纯林植物N/P<14,但因其具有较高的N、P吸收能力,且N转换率显著高于P,故不认为山杨纯林植物受到N限制。     

云南普洱季风常绿阔叶林优势物种不同生长阶段叶片碳、氮、磷化学计量特征

为探索植物叶片氮(N)、磷(P)、碳(C)生态化学计量特征随植物生长发育的变化规律, 在普洱季风常绿阔叶林中, 选取6种优势植物种(红锥(Castanopsis hystrix)、短刺锥(Castanopsis echidnocarpa)、泥柯(Lithocarpus fenestratus)、截果柯(Lithocarpus truncatus)、西南木荷(Schima wallichii)、茶梨(Anneslea fragrans))采集叶片, 分析其N、P、C含量及化学计量比随植物生长发育的变化。结果显示: 6种植物在不同生长阶段的N含量变化范围为7.90-17.72 mg·g^-1, P为0.34-1.39 mg·g^-1, C为458.48-516.87 mg·g^-1, C:N为28.04-65.70, N:P为11.41-63.50, C:P为355.23-1878.17, 且不同生长阶段6种植物及总体叶片N、P、C含量及其化学计量比变化趋势各异。在变异系数上, N:P比整体变异最大, 为36.46% (变化范围19.19%-91.65%), 其次为C:P, 为34.80% (变化范围15.99%-91.60%), C的整体变异最小, 为3.12% (变化范围1.61%-5.89%)。变异来源分析结果显示, N含量、C含量、C:N、N:P及C:P均主要受植物生长阶段的影响, 而P含量主要受物种与生长阶段的交互作用影响。     

西双版纳热带雨林土壤与叶片生态化学计量特征的干湿度效应

基于地理格局对西双版纳热带雨林的干湿度梯度效应和生态化学计量学的研究思路,结合野外试验监测和室内分析,对西双版纳热带雨林土壤-植物系统元素化学计量特征对海拔和干湿度效应响应进行了研究探讨,结果发现:西双版纳热带雨林土壤和叶片碳氮磷化学计量特征均不同程度的受到海拔和干湿季影响。季雨林与山地雨林的水热梯度受海拔梯度重要影响,随海拔梯度升高,土壤含水率变化显著,且含水率在干湿季均对土壤有机碳(SOC)存在显著影响(P0.01),雨季其对土壤全氮(STN)和土壤全磷(STP)的影响要显著于干季;叶片全磷(TP)随含水率的增大而升高,而叶片全氮(TN)在干季会随含水率的升高而增大,雨季含水率升高到一定程度时会抑制TN含量的增加并出现单峰现象;而土壤C/P与海拔和干季土壤含水率的极显著相关性(P0.01)及干季叶片C/N与叶片含水率的显著相关关系(P0.05)说明,干季水分匮乏条件下,土壤含水率影响土壤P的矿化度和植物对P的吸收利用水平,而且叶片C/N对反馈植物水分含量具有明显指示作用。因此,水热梯度是土壤-叶片系统碳氮磷生态化学计量特征变化的重要驱动因素。此外,全球变化区域响应方面,多雨高温可能会削弱季雨林叶片C的同化能力,且叶N含量降低,但受氮沉降的影响,对C/N的影响尚无法确定;由于P循环对其他元素的耦合作用,雨林土壤-叶片系统的元素循环周期将会被缩短,但干季山地雨林植物生态系统P的限制作用有可能会减弱。     

氮添加对武夷山亚热带常绿阔叶林植物叶片氮磷化学计量特征的影响

该文以福建武夷山亚热带常绿阔叶林为研究对象, 通过设置3个氮(N)添加梯度的野外实验, 研究了群落内乔木植物、灌木植物、草本植物、蕨类植物和苔藓植物叶片N、磷(P)化学计量特征对N沉降的响应, 以及不同功能群和物种化学计量特征对N沉降响应的差异。在已开展5年人工N添加的样地内, 3年的监测结果表明: N添加整体上提高了植物叶片N含量, 草本层植物叶片N含量对N添加的响应比乔木层和灌木层植物更加敏感, 优势种米槠(Castanopsis carlesii)、草本植物砂仁(Amomum villosum)、蕨类植物狗脊(Woodwardia japonica)的叶片N含量显著增加。N添加整体上增加了植物叶片P含量, 乔木层植物和灌木层植物叶片P含量没有显著变化, 草本层植物叶片P含量显著增加, 而苔藓植物叶片P含量显著减少。N添加促使武夷山亚热带常绿阔叶林植物叶片N:P由18.67上升至19.72, 加剧了植物生长的P限制; 乔木物种N:P的变化较灌木和草本物种更加稳定。N添加条件下, 植物叶片N:P的变化主要受到叶片P含量而非N含量变化的影响, N添加对生态系统P循环的影响显著。     

大兴安岭泥炭地植物叶片碳氮磷含量及其化学计量学特征

叶片碳(C)、氮(N)、磷(P)含量及其化学计量特征为植物养分状况和元素限制性提供依据。为了解不同生活型植物叶片C、N、P化学计量特征的变化,该研究测定、分析了大兴安岭地区18个泥炭地常见的3种草本植物——白毛羊胡子草(Eriophorum vaginatum)、玉簪薹草(Carex globularis)、小叶章(Deyeuxia angustifolia), 5种落叶灌木——柴桦(Betula fruticosa)、越桔柳(Salix myrtilloides)、细叶沼柳(Salix rosmarinifolia)、笃斯越桔(Vaccinium uliginosum)、越桔(Vaccinium vitis-idaea)和3种常绿灌木——杜香(Ledum palustre)、地桂(Chamaedaphne calyculata)、头花杜鹃(Rhododendron capitatum)的叶片C、N、P含量。结果表明: (1)落叶和常绿灌木叶片C、N、P含量总体高于草本植物而C:N、C:P、N:P低于草本植物, 说明不同生活型植物具有不同的养分利用策略,灌木叶片C、N、P储存高于草本植物而N、P利用效率低于草本植物; (2)小叶章和头花杜鹃叶片N:P小于10, 同时其N含量小于全球植物叶片平均N含量, 相比其他植物来说更易受N限制; (3)采样地点解释了叶片C、N、P指标变异的12.8%-40.8%, 植物种类对叶片C、N、P指标变异的解释量占9.3%-25.5%; (4)草本植物C、N、P指标的地点间变异系数高于落叶和常绿灌木, 草本植物C、N、P指标对地点因素变化的响应较灌木敏感; (5)草本植物N含量种间变异系数高于落叶和常绿灌木, 落叶灌木P含量种间变异系数高于草本植物和常绿灌木, 草本植物和落叶灌木N、P吸收的种间生理分化较常绿灌木高。     

兴安落叶松(Larix gmelinii Rupr.)叶片养分的空间分布格局

对中国东北温带森林生态系统主要树种兴安落叶松(Larix gmelinii Rupr.)24个采样点72个叶片样品有机碳(C)、全氮(N)、全磷(P)和全钾(K)的化学组成、地理分布格局及其与气候因子的关系进行了研究.结果表明,叶片C、N、P和K含量的几何平均数分别为543.970、16.902、2.373mg/g和14.625mg/g,且叶片的C含量>N含量>K含量>P含量;叶片的C/N、C/P和N/P分别为32.183、229.226和7.123.随纬度的增加、年均温度和年均降雨量的降低,兴安落叶松叶片C、N含量和N/P显著降低,叶片C/N和K含量显著升高,叶片P含量和C/P的变化没有达到显著水平.叶片N含量随纬度与年均温度的变化与全球及其它大尺度的研究结果相反,而N/P与其一致,这与在该区域的其它物种的研究结果基本一致.这可能是由于在本研究区域北部寒温带越往高纬度地区年均温度和年均降雨量越低、生长季越短,因此成土作用弱导致植物可以吸收利用的养分越少,但是由于植物显著降低的N含量和变化不明显的P含量导致了叶片N/P随纬度的增加和年均温度和年均降雨量的降低而降低,这与全球尺度的研究结果一致.兴安落叶松叶片养分分布格局与全球尺度和中国区域研究结果的差异说明了加强区域叶片养分特征研究的重要性.叶片养分与气候因子的显著线性相关说明气候因子是影响叶片养分特征的一个主要因子.     

Patterns of leaf N:P stoichiometry along climatic gradients in sandy region,north of China

Aims Biological and environmental factors determine geographic patterns of plant nutrient stoichiometry jointly. Unraveling the distribution pattern and the potential drivers of nutrient stoichiometry is therefore critical for understanding the adaptive strategies and biogeochemistry cycling. Aimed to determine how leaf nitrogen (N):phosphorus (P) stoichiometry is linked to biological and environmental factors, we investigated the patterns of psammophyte leaf N:P stoichiometry in sandy region, northern China, and the potential factors affecting leaf N:P stoichiometry were explored.Methods Based on 10 m × 10 m quadrates survey, the leaves of 352 dominant psammophyte samples belonging to 167 species were collected cross a 3000 km east-west transect in sandy environments, northern China. The samples were further classified into the following groups on the basis of plant life forms and functional groups (photosynthesis pathways and nitrogen fixation). The structural equation modeling was employed to clarify the importance of biological and environmental factors on leaf N:P stoichiometry.Important findings Generally, the higher leaf N and P concentrations, but lower N:P ratio were found in psammophyte compared with other ecosystems. Mean annual temperature (MAT) influenced the leaf N, P concentrations negatively, while mean annual precipitation (MAP) did positively. MAP played greater influence on leaf N, P concentrations than MAT did. MAP affected leaf N, P concentrations directly or indirectly through phylogeny, while MAT only shown direct effect on leaf N concentration. The psammophyte was more limited by N, rather P, in sandy region of northern China. These results suggest that phylogeny of psammophyte and climate jointly influence leaf N:P stoichiometry, and the results could be helpful in modeling biogeochemical nutrients cycling in vulnerable ecosystems like sandy environment.     

Leaf C,N, and P concentrations and their stoichiometry in peatland plants of Da Hinggan Ling,China

叶片碳(C)、氮(N)、磷(P)含量及其化学计量特征为植物养分状况和元素限制性提供依据。为了解不同生活型植物叶片C、N、P化学计量特征的变化,该研究测定、分析了大兴安岭地区18个泥炭地常见的3种草本植物——白毛羊胡子草(Eriophorum vaginatum)、玉簪薹草(Carex globularis)、小叶章(Deyeuxia angustifolia), 5种落叶灌木——柴桦(Betula fruticosa)、越桔柳(Salix myrtilloides)、细叶沼柳(Salix rosmarinifolia)、笃斯越桔(Vaccinium uliginosum)、越桔(Vaccinium vitis-idaea)和3种常绿灌木——杜香(Ledum palustre)、地桂(Chamaedaphne calyculata)、头花杜鹃(Rhododendron capitatum)的叶片C、N、P含量。结果表明: (1)落叶和常绿灌木叶片C、N、P含量总体高于草本植物而C:N、C:P、N:P低于草本植物, 说明不同生活型植物具有不同的养分利用策略,灌木叶片C、N、P储存高于草本植物而N、P利用效率低于草本植物; (2)小叶章和头花杜鹃叶片N:P小于10, 同时其N含量小于全球植物叶片平均N含量, 相比其他植物来说更易受N限制; (3)采样地点解释了叶片C、N、P指标变异的12.8%-40.8%, 植物种类对叶片C、N、P指标变异的解释量占9.3%-25.5%; (4)草本植物C、N、P指标的地点间变异系数高于落叶和常绿灌木, 草本植物C、N、P指标对地点因素变化的响应较灌木敏感; (5)草本植物N含量种间变异系数高于落叶和常绿灌木, 落叶灌木P含量种间变异系数高于草本植物和常绿灌木, 草本植物和落叶灌木N、P吸收的种间生理分化较常绿灌木高。     

Carbon,nitrogen and phosphorus stoichiometry in leaves and fine roots of dominant plants in Horqin Sandy Land

Aims The stoichiometric characteristics of carbon (C), nitrogen (N) and phosphorus (P) in plant organism is vital to understand plant adaptation to environment. In particular, the correlations of elemental stoichiometric characteristics between leaf and fine root could provide insights into the interaction and balance among the plant elements, nutrient use strategies and plant response to global change.Methods We measured C, N, P contents and C:N, C:P, N:P in leaves and fine roots of 60 dominant plants in Horqin sandy land. The 60 plant species were classified into five life forms and two categories such as perennial forb, annual forb, perennial grass, annual grass, shrub, legume, and non-legume. We statistically analyzed the differences and correlations of C, N and P stoichiometry either between fine root and leaf or among five life forms.Important findings The average C, N and P concentrations in leaves of 60 plant species in Horqin sandy land are 424.20 mg·g^-1, 25.60 mg·g^-1 and 2.10 mg·g^-1, respectively. In fine roots, the corresponding element concentrations are 434.03 mg·g^-1, 13.54 mg·g^-1, 1.13 mg·g^-1. N and P concentrations in leaf are approximately twice as high as averages in fine root. Furthermore, similar N:P between leaf and fine root indicates conservative characteristic of elemental stoichiometry in plant organism, suggesting that nutrients distribution is proportional between aboveground and underground of plants. There are significant difference of C, N, P, C:N, C:P and N:P in leaf and root among five life forms. N and P in forb and C:N and C:P in grass are averagely higher than those in other life forms. N:P in annual forb and grass, however, are lower than those in other life forms. C, N in legume are higher than those in non-legume, while C:N in legume is lower than in non-legume. These results imply that nutrient use strategies are significantly different among plant life forms. Correlations analysis showed that N and P in leaf or fine root positively correlated, but C and N, C and P in fine root negatively correlated, suggesting coupling relationship among C, N and P in leaf and fine root. Subsequently, we detected positively significant correlations in C, N, P and their ratios between leaf and fine root, suggesting proportional distribution of photosynthate and nutrient between aboveground and underground during plant growth. Generally, these results supplied fundamental data to understand mass turnover and nutrients cycling of leaves and roots in sand land.     

Leaf nitrogen and phosphorus concentration and the empirical regulations in dominant woody plants of shrublands across southern China

Aims Understanding the changes in N and P concentration in plant organs along the environmental gradients can provide meaningful information to reveal the underline mechanisms for the geochemical cycles and adaptation strategies of plants to the changing environment. In this paper, we aimed to answer: (1) How did the N and P concentration in leaves of evergreen and deciduous woody plants change along the environmental gradients? (2) What were the main factors regulating the N and P concentration in leaves of woody plants in the shrublands across southern China?
Methods Using a stratified random sampling method, we sampled 193 dominant woody plants in 462 sites of 12 provinces in southern China. Leaf samples of dominant woody plants, including 91 evergreen and 102 deciduous shrubs, and soil samples at each site were collected. N and P concentration of the leaves and soils were measured after lapping and sieving. Kruskal-Wallis and Nemenyi tests were applied to quantify the difference among the organs and life-forms. For each life-form, the binary linear regression was used to estimate the relationships between leaf log [N] and log [P] concentration and mean annual air temperature (MAT), mean annual precipitation (MAP) and log soil total [N], [P]. The effects of climate, soil and plant life-form on leaf chemical traits were modeled through the general linear models (GLMs) and F-tests.
Important findings 1) The geometric means of leaf N and P concentrations of the dominant woody plants were 16.57 mg·g^-1 and 1.02 mg·g^-1, respectively. The N and P concentration in leaves (17.91 mg·g^-1, 1.14 mg·g^-1) of deciduous woody plants was higher than those of evergreen woody plants (15.19 mg·g^-1, 0.89 mg·g^-1). The dependent of leaf P concentration on environmental (climate and soil) appeared more variable than N concentration. 2) Leaf N and P in evergreen woody plants decreased with MAT and but increased with MAP, whereas those in deciduous woody plants showed opposite trends. With increase in MAP, leaf P concentration decreased for both evergreen and deciduous woody plants. 3) Soil N concentration had no significant effect on both evergreen and deciduous woody plants. However, leaf P concentration of the tow increased significantly with soil P concentration. (4) GLMs showed that plant growth form explained 7.6% and 14.4% of variation in leaf N and P, respectively. MAP and soil P concentration contributed 0.8% and 16.4% of the variation in leaf P, respectively. These results suggested that leaf N was mainly influenced by plant growth form, while leaf P concentration was driven by soil, plant life-form, and climate at our study sites.     

神农架常绿落叶阔叶混交林碳氮磷化学计量比

生态化学计量学是研究生态过程中化学元素平衡的科学, 碳(C)、氮(N)、磷(P)化学计量比是生态系统过程及其功能的重要特征。该研究测定了神农架常绿落叶阔叶混交林植物器官、凋落物及土壤的C、N、P含量, 利用生物量加权法计算其化学计量比, 并分析该生态系统不同组分间及不同器官间化学计量比的差异。研究结果发现: 在不同组分之间, C含量、C:N及C:P表现为植物>凋落物>土壤; N、P含量及N:P表现为凋落物>植物>土壤。在不同植物器官间, C含量的差异较小, 其变异系数相对N、P含量较低且保持稳定; N、P含量为叶片最高且变异系数最低; N:P为树皮最高, 而枝的变异系数最低。常绿与落叶树种的叶片N、P含量差异显著。与不同森林类型的化学计量比相比, 该常绿落叶阔叶混交林植物群落的C:P及N:P较低, 凋落物的C:P及N:P较高, 土壤的C、N、P化学计量比与亚热带常绿阔叶林基本一致, 生态系统的C:N相对较低。利用生物量加权法计算得到的该森林生态系统不同组分的C、N、P化学计量比的大小关系与前人利用枝叶取样算术平均的结果存在较大差异。C、N、P含量及其化学计量比在不同器官的分配及内稳性与器官的生理功能关系密切。     

Changes in soil-microbe-exoenzyme C:N:P stoichiometry along an altitudinal gradient in Mt. Datudingzi,Northeast China

海拔变化导致温度、水分、植被等条件的改变会显著影响土壤碳(C_soil)、氮(N_soil)、磷(P_soil)含量及其化学计量特征, 土壤微生物如何通过调整自身生物量和胞外酶化学计量特征进行适应仍不明确。为了研究海拔梯度变化对土壤微生物生物量和胞外酶活性的影响, 探索土壤-微生物-胞外酶C:N:P化学计量特征间的协变性, 该文以黑龙江省雪乡大秃顶子山800、1 100、1 600和1 700 m分布的典型生态系统(针阔混交林、针叶林、岳桦林和草地)为研究对象, 测定其C_soil、N_soil、P_soil含量, 微生物生物量C (C_mic)、N (N_mic)、P (P_mic)含量, 以及微生物获取C (β-1, 4-葡萄糖苷酶, BG), N (几丁质酶, NAG), P (酸性磷酸酶, AP)资源的相关胞外酶活性。结果表明: (1)海拔梯度变化对C_soil和C_mic含量没有显著影响; 不同海拔间土壤和微生物生物量N、P含量存在显著差异。(2) BG和NAG活性随着海拔的升高呈现显著降低趋势, 表明海拔升高导致的温度降低抑制了微生物的活性。(3)海拔对土壤C:N、微生物C:N:P以及胞外酶C:N:P均具有显著影响。胞外酶C:N:P随着微生物与土壤间C:N:P化学计量不平衡性(土壤C:N:P与微生物C:N:P的比值)的增加而逐渐降低。微生物可以通过调整自身生物量以及胞外酶C:N:P适应土壤化学计量特征的变异, 该结果支持了微生物的资源分配理论。     

Stoichiometric characteristics of carbon,nitrogen and phosphorus of Sibiraea angustata shrub on the eastern Qinghai-Xizang Plateau

Aims Little is known about the stoichiometric characteristics of carbon (C), nitrogen (N) and phosphorus (P) in plateau shrubs across China. Sibiraea angustata is a typical and representative shrub species on the eastern Qinghai- Xizang Plateau, and exploring its C, N and P distribution patterns and stoichiometric properties in different organs (including root, shoot, leaf, twig and fruit) would help us better understand the mechanisms of C, N and P cycling and balance in the S. angustata dominated shrub ecosystem.
Methods Sixteen sampling sites were selected on the eastern Qinghai-Xizang Plateau by the stratified sampling method. The height and coverage of the dominant shrubs, latitude, longitude and altitude of the sites were recorded. Three 5 m × 5 m plots were selected at each site. At least 128 biological samples of plant organs of S. angustata were collected and measured, respectively. The C and N concentrations of plant samples were analyzed using an elemental analyzer (2400 II CHNS). The P concentration was analyzed using the molydate/ascorbic acid method after H₂SO₄-H₂O₂ digestion.
Important findings The C, N and P concentrations of different organs followed the order of: shoot (495.07 g·kg^-1) > twig (483.37 g·kg^-1) > fruit (480.35 g·kg^-1) > root (468.47 g·kg^-1) > leaf (466.33 g·kg^-1); leaf (22.27 g·kg^-1) > fruit (19.74 g·kg^-1) > twig (7.98 g·kg^-1) > shoot (4.54 g·kg^-1) > root (4.00 g·kg^-1) and fruit (2.85 g·kg^-1) > leaf (1.92 g·kg^-1) > twig (0.96 g·kg^-1) > root (0.52 g·kg^-1) > shoot (0.45 g·kg^-1), respectively. The ranges of the coefficient of variation (CV) for C, N and P concentrations were 1.71%-4.44%, 14.49%-25.50% and 11.46%-46.15%, respectively. Specifically, the C concentration was relatively high and stable, and the maximum CV values for N and P were found in roots. The N:P value of different organs varied from 7.12-12.41 and the minimum CV for N:P was found in twig, which indicated that N:P in twig had higher internal stability. In addition, correlation analysis indicated that the C concentration was significantly negatively correlated with N and P concentrations and correlation coefficients were -0.407 and -0.342, respectively. However, N concentration had dramatically positive correlation with P concentration and the correlation coefficient was 0.814. These results also could indicate that the C, N and P stoichiometric characteristics in the S. angustata shrub accorded with the homeostatic mechanism and growth rate hypothesis to some extent, the distributions of C, N and P concentrations were closely related to the function of the organs and it should be prudent to use ecological stoichiometric ratios to judge the condition of nutrient limitation at the species level.     

Relationships between below-ground biomass and foliar N:P stoichiometry along climatic and altitudinal gradients of the Chinese grassland transect

N and P concentrations and their ratios were determined for 132 foliar and 120 below-ground biomass (BGB) samples obtained at 132 sites along the 4500 km Chinese Grassland Transect (CGT) across the Inner Mongolian and Qinghai–Tibet Plateaus. Patterns of foliar and BGB N, P and their ratio (N/P) at the community level were related to altitude, temperature, and precipitation gradients. Also, patterns of relative N and P foliar and BGB concentrations were determined (N_F/B, foliar N/BGB N; P_F/B, foliar P/BGB P). The relationship between foliar N concentrations and mean annual temperature (MAT) was negative, agreeing with the Temperature-Plant Physiological hypothesis, whereas BGB N decreased with decreasing MAT, supporting the Biogeochemical hypothesis. Patterns of BGB N varying with altitude, MAP and MAT differed from the patterns for leaf N, which may indicate differences in nutrient allocation and utilization by leaves and BGB. N_F/B and P_F/B may reflect trade-offs by plants for N and P in leaves and BGB. For the entire CGT, N_F/B and P_F/B increased as altitude increased. N_F/B was positively related with MAP but negatively related with MAT, while P_F/B showed no correlations with MAP and MAT. Results suggest that ecological stoichiometry at the community level is similar to that at the species level. Strategies of nutrient utilization by leaves and BGB are indicated to be different, and abiotic environmental conditions could influence the stoichiometric characteristics and nutrient allocation to leaves and BGB.     

Impacts of nitrogen addition on foliar nitrogen and phosphorus stoichiometry in a subtropical evergreen broad-leaved forest in Mount Wuyi

Aims Our purpose was to explore the effects of nitrogen addition on foliar nitrogen (N), phosphorus (P) and N:P stoichiometry and to assess their differences among different species and functional groups.
Methods N addition experiment has been conducted in a subtropical evergreen broad-leaved forest in Mount Wuyi, Fujian Province since 2011. Foliar concentrations of nitrogen and phosphorus were measured and foliar stoichiometry was estimated in tree, shrub, herb, fern and moss species following the N addition treatments from 2013 to 2015.
Important findings Generally, foliar N increased for almost all species and herbaceous plants are much more sensitive than trees and shrubs under N addition. Foliar N of Castanopsis carlesii, Amomum villosum, Woodwardia japonica increased significantly under N addition. Foliar P for most species was sensitive to the N addition. Foliar P of herbaceous plants increased significantly but foliar P of Leucobryum chlorophyllosum decreased significantly. The results showed the subtropical evergreen forest in Mount Wuyi was mainly limited by P and mean foliar N:P ratios enhanced from 18.67 to 19.72 under N addition, indicating that the strength of P limitation was enhanced by N addition. N:P ratios of the dominant arboreal species in the communities tended to be stable, while N:P ratios of herbaceous plants and shrubs increased. The changes in N:P ratios were mainly determined by P dynamics instead of N dynamics under N addition, and our results confirmed that increasing N availability can affect P cycling.