不同氮磷比处理对甘草生长与生态化学计量特征的影响

大气氮(N)沉降增加加速了生态系统N循环,导致生态系统磷(P)需求增加。开展不同N:P处理对荒漠草原植物生长和生态化学计量特征影响的研究,不仅可为预测长期大气N沉降增加条件下植物和土壤的相互作用提供新思路,而且可为全球变化背景下我国北方草地植被的可持续管理提供科学指导。该文通过2013–2014年针对甘草(Glycyrrhiza uralensis)设立的不同N:P的盆栽控制试验,研究了不同N:P处理对甘草生物量和碳(C)、N、P化学计量学特征(叶片、根系和土壤)的影响,比较了C:N:P化学计量学特征在叶片、根系和土壤3个库间的差异和联系,探讨了土壤C:N:P化学计量比对甘草生长和养分摄取的指示作用。结果显示:N:P的适当减小降低了土壤和甘草(叶片和根系)的C:P和N:P,提高了甘草地上和地下生物量,说明适量的P添加提高了土壤P有效性和甘草P摄取能力、促进了甘草生长和生物量积累。但过低的N:P处理(高P添加)使土壤C:P和N:P显著下降,抑制了甘草对N的摄取,从而不利于甘草生长;甘草叶片和根系(尤其叶片)C:N:P化学计量学特征均与土壤C:N:P化学计量学特征存在不同程度的相关性,意味着土壤C、N、P及其计量关系的改变会直接作用于植物。以上结果表明,适当的人为P添加可通过调节土壤和植物叶片C:N:P化学计量学特征,缓解土壤和植物间P的供需压力,从而减缓长期大气N沉降增加对荒漠草原群落结构的不利影响。     

氮添加对荒漠草原植物群落组成与微生物生物量生态化学计量特征的影响

大气氮(N)沉降增加加速了土壤N循环, 引起微生物生物量碳(C):N:磷(P)生态化学计量关系失衡、植物种丧失和生态系统服务功能降低等问题。开展N添加下植物群落组成与微生物生物量生态化学计量特征关系的研究, 可为深入了解N沉降增加引起植物多样性降低的机理提供新思路。该文以宁夏荒漠草原为研究对象, 探讨了N添加下植物生物量和群落多样性的变化趋势, 分析了微生物生物量C:N:P生态化学计量特征独立及其与其他土壤因子共同对植物群落组成的影响。结果表明: N添加下猪毛菜(Salsola collina)生物量呈显著增加趋势, 牛枝子(Lespedeza potaninii)生物量呈逐渐降低趋势, 其他植物种生物量亦呈降低趋势但未达到显著水平; 沿N添加梯度, Shannon-Wiener多样性指数、Simpson优势度指数和Patrick丰富度指数均呈先略有增加后逐渐降低的趋势; N添加提高了微生物生物量N含量和N:P, 降低了微生物生物量C:N; 植物群落组成与微生物生物量N含量、微生物生物量C:N、微生物生物量N:P、土壤NO₃ ^--N浓度、土壤NH₄ ⁺-N浓度以及土壤全P含量有较强的相关关系; 微生物生物量C:N:P生态化学计量特征对植物种群生物量和群落多样性变化的独立解释力较弱, 但却与其他土壤因子共同解释了较大变差, 意味着N添加下微生物生物量C:N:P生态化学计量特征对植物群落组成的影响与其他土壤因子高度相关。     

氮磷添加对荒漠草原植物群落多样性和土壤C:N:P生态化学计量特征的影响

为了深入了解P添加是否有助于缓解N沉降增加引起的植物群落多样性降低等问题,以宁夏盐池县长期围封的荒漠草原为研究对象,探讨了连续两年(2015—2016年) 5 g/m~2/a的N水平下,P添加对植物生物量、群落多样性和土壤C∶N∶P生态化学计量特征的影响,分析了植物群落多样性与土壤C∶N∶P比及其他关键因子的关系。结果表明:少量N添加下,增施P肥促进了植物生物量积累,但中高量P添加抑制了多数植物生长,使牛枝子(Lespedeza potaninii)、草木樨状黄芪(Astragalus melilotoides)和苦豆子(Sophora alopecuroides)等物种重要值降低;随着P添加量增加,Shannon-Wiener多样性指数和Patrick丰富度指数先增加后降低,Simpson优势度指数逐渐增加,Pielou均匀度指数变化幅度较小;随着P添加量增加,土壤C∶P和N∶P比逐渐降低;土壤N∶P比、C∶P比、全P含量、速效P浓度以及微生物量C∶P比与植物群落多样性关系密切,意味着N沉降增加下趋于解耦的土壤元素平衡关系可能会影响到植物群落组成。综合以上结果,适量P添加可以通过提高土壤P有效性、增加凋落物归还量和刺激微生物P释放等途径,调节土壤P供给和植物P需求间的压力,从而缓解N添加引起的植物群落多样性降低。     

氮添加对荒漠草原植物群落组成与微生物生物量生态化学计量特征的影响

大气氮(N)沉降增加加速了土壤N循环,引起微生物生物量碳(C):N:磷(P)生态化学计量关系失衡、植物种丧失和生态系统服务功能降低等问题。开展N添加下植物群落组成与微生物生物量生态化学计量特征关系的研究,可为深入了解N沉降增加引起植物多样性降低的机理提供新思路。该文以宁夏荒漠草原为研究对象,探讨了N添加下植物生物量和群落多样性的变化趋势,分析了微生物生物量C:N:P生态化学计量特征独立及其与其他土壤因子共同对植物群落组成的影响。结果表明:N添加下猪毛菜(Salsolacollina)生物量呈显著增加趋势,牛枝子(Lespedezapotaninii)生物量呈逐渐降低趋势,其他植物种生物量亦呈降低趋势但未达到显著水平;沿N添加梯度,Shannon-Wiener多样性指数、Simpson优势度指数和Patrick丰富度指数均呈先略有增加后逐渐降低的趋势;N添加提高了微生物生物量N含量和N:P,降低了微生物生物量C:N;植物群落组成与微生物生物量N含量、微生物生物量C:N、微生物生物量N:P、土壤NO3--N浓度、土壤NH4+-N浓度以及土壤全P含量有较强的相关关系;微生物生物量C:N:P生态化学计量特征对植物种群生物量和群落多样性变化的独立解释力较弱,但却与其他土壤因子共同解释了较大变差,意味着N添加下微生物生物量C:N:P生态化学计量特征对植物群落组成的影响与其他土壤因子高度相关。     

氮肥添加对青藏高原高寒草甸6个群落优势种生态化学计量学特征的影响

以青藏高原高寒草甸为研究对象, 通过人工氮肥添加试验, 研究6个群落优势种在不同施氮(N)水平下叶片碳(C)、N、磷(P)元素含量的变化以及生态化学计量学特征。结果表明: 自然条件下, 6个物种叶片N、P质量浓度存在显著的差异, 表现为: 黄花棘豆(Oxytropis ochrocephala)最高, 为24.5和2.51 g·kg^-1, 其叶片N含量低于而P含量高于我国其他草地的豆科植物; 其余5个物种叶片N、P质量浓度分别为11.5-18.1和1.49-1.72 g·kg^-1, 嵩草(Kobresia myosuroides)叶片N含量最低, 垂穗披碱草(Elymus nutans)叶片P含量最低, 与我国其他区域的研究结果相比, 其叶片N和P含量均低于我国其他草地非豆科植物。随氮素添加量的增大, 6种群落优势种叶片的C和P含量保持不变; 其他5种植物叶片N含量显著增加, 黄花棘豆叶片N含量保持不变。未添加氮肥时, 6种植物叶片N:P为7.3-11.2, 说明该区植物生长更多地受N限制。随N添加量的增加, 除黄花棘豆外, 其他5种植物叶片N:P大于16, 表现为植物生长受P限制。综合研究表明, 青藏草原高寒草甸植物叶片N含量较低, 植物受N影响显著, 但不同物种对N的添加反应不同, 豆科植物黄花棘豆叶片对N添加不敏感, 其他5个物种叶片全N含量随着N添加量的升高而增加, 该研究结果可为高寒草甸科学施肥提供理论依据。     

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。     

氮磷供给对荒漠草原土壤和白草C∶N∶P化学计量特征的影响

大气氮(N)沉降增加是全球变化的一个重要方面。长期N沉降增加会提高生态系统N:磷(P)比,导致系统P限制增加以及植物P需求增强。该试验通过对白草(Pennisetum centrasiaticum)设立的N∶P供给(在统一施用N10.0g·m~(-2)·a~(-1)的基础上,通过改变P施用量,形成6个N∶P处理水平)盆栽控制试验,研究了连续2年(2013~2014年)N∶P供给处理对土壤和白草碳(C)∶N∶P化学计量特征的影响,并分析了C∶N∶P化学计量特征对白草生长和养分利用的指示意义。结果显示:(1)降低N∶P供给(提高P施用量)能够显著降低土壤和白草的C∶P和N∶P,缓解白草生长的P受限性,从而促进白草的生物量积累。(2)随着N∶P供给进一步降低,土壤N受限性增加。(3)白草通过提高其枯叶N回收能力,减少对土壤N库的依赖,反映了白草对N受限环境的弹性适应。研究表明,人为适当的添加P能够通过调节土壤和植物C、N、P计量平衡关系,减轻土壤和植物间P的供需压力,从而缓解N添加引起的荒漠草原P受限性增强。该研究结果可为N沉降增加背景下脆弱生态系统的适应性管理提供科学指导。     

Effects of N addition on ecological stoichiometric characteristics in six dominant plant species of alpine meadow on the Qinghai-Xizang Plateau,China

以青藏高原高寒草甸为研究对象, 通过人工氮肥添加试验, 研究6个群落优势种在不同施氮(N)水平下叶片碳(C)、N、磷(P)元素含量的变化以及生态化学计量学特征。结果表明: 自然条件下, 6个物种叶片N、P质量浓度存在显著的差异, 表现为: 黄花棘豆(Oxytropis ochrocephala)最高, 为24.5和2.51 g·kg^-1, 其叶片N含量低于而P含量高于我国其他草地的豆科植物; 其余5个物种叶片N、P质量浓度分别为11.5-18.1和1.49-1.72 g·kg^-1, 嵩草(Kobresia myosuroides)叶片N含量最低, 垂穗披碱草(Elymus nutans)叶片P含量最低, 与我国其他区域的研究结果相比, 其叶片N和P含量均低于我国其他草地非豆科植物。随氮素添加量的增大, 6种群落优势种叶片的C和P含量保持不变; 其他5种植物叶片N含量显著增加, 黄花棘豆叶片N含量保持不变。未添加氮肥时, 6种植物叶片N:P为7.3-11.2, 说明该区植物生长更多地受N限制。随N添加量的增加, 除黄花棘豆外, 其他5种植物叶片N:P大于16, 表现为植物生长受P限制。综合研究表明, 青藏草原高寒草甸植物叶片N含量较低, 植物受N影响显著, 但不同物种对N的添加反应不同, 豆科植物黄花棘豆叶片对N添加不敏感, 其他5个物种叶片全N含量随着N添加量的升高而增加, 该研究结果可为高寒草甸科学施肥提供理论依据。     

典型草原建群种羊草对氮磷添加的生理生态响应

由于人类活动和气候变化的共同作用, 大气氮(N)沉降日益加剧, 使得陆地生态系统中的可利用性N显著增加, 生态系统更易受其他元素如磷(P)的限制。然而, 目前关于N、P养分添加对草原生态系统不同组织水平的影响研究较少, 相关机制尚不清楚。该文以内蒙古典型羊草(Leymus chinensis)草原为研究对象, 通过连续两年(2011-2012年)的N和P养分添加实验, 研究建群种羊草的生理生态性状、种群生物量和群落初级生产力对N、P添加的响应及其适应机制。结果表明: 羊草草原不同组织水平对N、P添加的响应不同。群落水平上, 地上净初级生产力在不同降水年份均受N和P元素的共同限制, N、P共同添加显著提高了地上净初级生产力; 物种水平上, N、P添加对羊草种群生物量和密度, 以及相对生物量均没有显著影响, 表明羊草能够维持种群的相对稳定; 个体水平上, 在正常降水年份(2011年), 羊草生长主要受N素限制, 而在湿润年份(2012年), 降水增加使得羊草生长没有受到明显的养分限制。羊草通过增加比叶面积、叶片大小和叶片N含量, 提高整体光合能力, 以促进个体生长。总之, 内蒙古典型草原群落净初级生产力受N、P元素共同限制, 作为建群种的羊草, 其对N、P添加的响应因组织水平而异, 也受年际间降水变化的影响。     

降水量及N添加对荒漠草原植物和土壤微生物C∶N∶P生态化学计量特征的影响

基于2017年在宁夏荒漠草原设立的降水量(减少50%、减少30%、自然降水、增加30%以及增加50%)和N添加(0和5 g·m~(-2)·a~(-1))野外试验,研究了植物和土壤微生物C∶N∶P生态化学计量特征,分析二者与土壤C∶N∶P生态化学计量特征及其他土壤因子的关系,以探讨降水格局改变和大气N沉降增加下荒漠草原植物和土壤微生物C∶N∶P平衡特征及其主要影响因素。结果表明:(1)减少降水量对荒漠草原植物和土壤微生物C∶N∶P生态化学计量特征的影响较小,反映了二者对短期干旱的适应性;增加降水量降低了植物和土壤微生物生物量N和P含量,不同程度地提高了C∶N和C∶P,但其影响程度与N添加有关。(2)增减降水量条件下, N添加对植物生态化学计量特征影响较小,但对土壤微生物C∶N∶P生态化学计量特征影响较大,尤其在增加降水量条件下表现得更明显,意味着降水激发了N添加效应。(3)植物全N含量、N∶P以及土壤微生物生物量N含量的内稳性较低,可较好地反映土壤N供给水平以及N、P受限类型。(4)与植物C∶N∶P生态化学计量特征关系较强的土壤因子为速效P含量、磷酸酶活性、电导率、C∶P和有机C含量,与土壤微生物C∶N∶P生态化学计量特征关系较强的土壤因子有电导率、含水量、蔗糖酶活性和磷酸酶活性,表明植物和土壤微生物C∶N∶P平衡特征主要受其他土壤因子的调控,而非土壤元素平衡关系。     

Responses of growth of four desert species to different N addition levels

Aims The increase in atmospheric N deposition has accelerated N cycling of ecosystems, thus altering the structure and function of ecosystems, especially in those limited by N availability. Studies on the response of plant growth to artificial N addition could provide basic data for a better understanding of how the structure of grasslands in northern China responds to increasing N deposition. Methods We investigated the seasonal dynamics of plant growth of four species after 2-year multi-level N addition in a field experiment conducted in a desert steppe of Ningxia in 2011. Plant biomass and the relative growth rate (RGR) of the studied species were measured and their relationships with C:N:P ratios of plants (community and leaf levels) and soils were analyzed. Important findings Results in 2012 showed that 2-year N addition promoted the growth of the four species and the effects were different among growth forms and were species-specific. In general, the plant biomass of the studied species was significantly correlated with leaf N concentration, leaf N:P ratio, community N pool, soil total N content and soil N:P ratio, while only weak relationships were observed between plant biomass and C:N and C:P ratios of plants and soils. In contrast, there was a significant linear relationship between RGR and N:P ratios both of plants and soils.Our results suggest that short-term N addition promoted the accumulation of plant biomass, and the species-specific responses to stimulated N addition can directly affect the structure of the desert steppe ecosystem. Plant N:P ratio and soil N:P ratio could indicate nutrient limitation of plant growth to a certain extent: N addition increased soil N content and N:P ratio, and thus relieved N limitation gradually. Once more N is available to plants, the growth of plants and the accumulation of community N was stimulated in turn.     

The relationship between relative growth rate and whole-plant C:N:P stoichiometry in plant seedlings grown under nutrient-enriched conditions

Aims Recent theories indicate that N is more in demand for plant growth than P; therefore, N concentration and N : C and N : P ratios are predicted to be positively correlated with relative growth rate (RGR) in plants under nutrient-enriched conditions. This prediction was tested in this study.Methods We examined the whole-plant concentrations of C, N and P and RGR, as well as the relationship between RGR and the concentrations and the ratios of N : C, P : C and N : P, for different harvest stages (the days after seed germination) of the seedlings of seven shrub species and four herbaceous species grown in N and P non-limiting conditions. The relationships among plant size, nutrient concentrations and ratios were subsequently determined.Important findings RGR was positively correlated with N concentration and the ratios of N : P and N : C when the data were pooled for all species and for each shrub species, but not for individual herbaceous species. However, the relationship between RGR and P concentration and P : C was not significantly correlated for either shrubs or herbs. The variation of N among harvest stages and species was much greater than that of P, and the variation in N : P ratio was determined primarily by changes in N concentration. The shrub species differed from the herbaceous species in their N and P concentrations, nutrient ratios and in intraspecific relationships between RGR and nutrient ratios. These differences possibly reflect differences in the capacity for P storage and biomass allocation patterns. In general, our data support recent theoretical predictions regarding the relationship between RGR and C : N : P stoichiometry, but they also show that species with different life forms differ in the relationships among RGR and C : N : P stoichimetries.     

Effects of different nitrogen:phosphorus levels on the growth and ecological stoichiometry of Glycyrrhiza uralensis北大核心CSCD

Aims The increase in atmospheric nitrogen (N) deposition has accelerated N cycling of ecosystems, probably resulting in increases in phosphorus (P) demand of ecosystems. Studies on the effects of artificial N:P treatment on the growth and carbon (C), N, P ecological stoichiometry of desert steppe species could provide not only a new insight into the forecasting of how the interaction between soils and plants responses to long-term atmospheric N deposition increase, but also a scientific guidance for sustainable management of grassland in northern China under global climate change. Methods Based on a pot-cultured experiment conducted for Glycyrrhiza uralensis (an N-fixing species) during 2013 to 2014, we studied the effects of different N:P supply ratios (all pots were treated with the same amount of N but with different amounts of P) on aboveground biomass, root biomass, root/shoot ratio, and C:N:P ecological stoichiometry both in G. uralensis (leaves and roots) and in soils. Additionally, through the correlation analyses between biomass and C:N:P ecological stoichiometry in leaves, roots, and soils, we compared the differences among the C:N:P ecological stoichiometry of the three pools, and discussed the indication of C:N:P ecological stoichiometry in soils for the growth and nutrient uptake of G. uralensis. Important findings The results showed that, reducing N:P decreased C:P and N:P ratios both in G. uralensis (leaves and roots) and in soils but increased aboveground biomass and root biomass of G. uralensis, indicating that low to moderate P addition increased P availability of soils and P uptake of G. uralensis. However, excessive low N:P (high P addition) led to great decreases in soil C:P and N:P ratios, thus hindering N uptake and the growth of G. uralensis. C:N:P ratios in the two pools of G. uralensis (especially in leaves) had close correlations with soil C:N:P ratio, indicating that the change in soil C:N:P ratio would have a direct influence on plants. Our results suggest that, through regulating C:N:P ratio in leaves and soils, appropriate amounts of P addition could balance soil P supply and plant P demand and compensate the opposite influences of long-term atmospheric N deposition increase on the structure of desert steppe.     

Effects of different nitrogen:phosphorus levels on the growth and ecological stoichiometry of Glycyrrhiza uralensis

Aims The increase in atmospheric nitrogen (N) deposition has accelerated N cycling of ecosystems, probably resulting in increases in phosphorus (P) demand of ecosystems. Studies on the effects of artificial N:P treatment on the growth and carbon (C), N, P ecological stoichiometry of desert steppe species could provide not only a new insight into the forecasting of how the interaction between soils and plants responses to long-term atmospheric N deposition increase, but also a scientific guidance for sustainable management of grassland in northern China under global climate change. Methods Based on a pot-cultured experiment conducted for Glycyrrhiza uralensis (an N-fixing species) during 2013 to 2014, we studied the effects of different N:P supply ratios (all pots were treated with the same amount of N but with different amounts of P) on aboveground biomass, root biomass, root/shoot ratio, and C:N:P ecological stoichiometry both in G. uralensis (leaves and roots) and in soils. Additionally, through the correlation analyses between biomass and C:N:P ecological stoichiometry in leaves, roots, and soils, we compared the differences among the C:N:P ecological stoichiometry of the three pools, and discussed the indication of C:N:P ecological stoichiometry in soils for the growth and nutrient uptake of G. uralensis. Important findings The results showed that, reducing N:P decreased C:P and N:P ratios both in G. uralensis (leaves and roots) and in soils but increased aboveground biomass and root biomass of G. uralensis, indicating that low to moderate P addition increased P availability of soils and P uptake of G. uralensis. However, excessive low N:P (high P addition) led to great decreases in soil C:P and N:P ratios, thus hindering N uptake and the growth of G. uralensis. C:N:P ratios in the two pools of G. uralensis (especially in leaves) had close correlations with soil C:N:P ratio, indicating that the change in soil C:N:P ratio would have a direct influence on plants. Our results suggest that, through regulating C:N:P ratio in leaves and soils, appropriate amounts of P addition could balance soil P supply and plant P demand and compensate the opposite influences of long-term atmospheric N deposition increase on the structure of desert steppe.     

Species richness loss after nutrient addition as affected by N:C ratios and phytohormone GA3 contents in an alpine meadow community

Aims From the light-competition hypothesis, competition for light is asymmetric and the observed increases in plant-size variability with increasingly denser canopies are primarily due to competition for light. Greater plant height provides pre-emptive access to light and produces increased height differences among species. The question is what produces these differences in plant height or height growth response among species in response to fertilization.Methods In 2009, a field experiment of N, P and N + P enrichments at three levels each was initiated in an alpine meadow on the northeast Qinghai-Tibet Plateau. Effects of fertilization on species richness, aboveground net primary production (ANPP), relative light intensity and plant height of different plant functional groups were determined. Festuca ovina (grass), Kobresia humilis (sedge), Oxytropis ochrocephala (legume), Taraxacum lugubre (rosette forb) and Geranium pylzowianum (upright forb) were selected as exemplars of each of the indicated functional groups. The N:C ratios in aboveground biomass, gibberellic acid (GA 3) concentrations in leaves, plant heights and height relative growth rate (RGR) of these exemplar species were analyzed in detail.Important findings Species richness of grasses significantly increased with increasing N + P levels. Species richness of legumes and upright forbs decreased after N and N + P additions. P addition had no significant effect on species richness. The effects of N + P addition on species richness and ANPP were consistently stronger than those of the single N or P fertilization. Reductions in species richness caused by nutrient addition paralleled the increases in ANPP and decreases in light intensity under the canopies, indicating indirect effect of nutrient addition on species richness via ANPP-induced light competition. The exemplar species that responded most positively to fertilization in height and RGR also displayed stronger increases in their GA 3 content and N:C ratios. GA 3 concentrations and N:C ratios were positively correlated with height RGR when the data were pooled for all species. The tallest and the fastest-growing grass, F. ovina, had the largest increase in N:C ratios and the highest leaf GA 3 concentrations after nutrient addition. These results indicated that differential responses of GA 3 concentrations and N:C ratios to fertilization were related to the inequality in plant heights among species.     

Functional groups' performances as influenced by nitrogen,phosphorus and nodule inhibition of legumes

Aims Nitrogen (N) and phosphorus (P) constitute essential elements for plant growth and their availability influence species diversity in herbaceous plant communities. Legumes exhibit relatively high abundance in N-limited soils. Moreover, the legumes' N:P ratios are much higher than those of the other plant species grown in the same site, probably because they are able to fix atmospheric N 2. The objective of this study was to determine how the relative proportion in N and P availability and the restriction of legumes to fix atmospheric N 2 affect: (i) the primary productivity of plant species, (ii) species composition and (iii) N and P concentrations of species.Methods In an outdoor experiment, mixtures containing grasses, legumes and non-legume forbs were established in 32 containers under four soil treatments (control, N addition, P addition and disinfected soil), in a completely randomized design with eight replicates. Plant growth was examined when N and P were limited in the control soil:sand mixture, in a pot experiment sown with Plantago lanceolata .Important findings The pot experiment indicated that both N and P were limiting for the growth of P. lanceolata. Soil treatments affected primary productivity and species composition. Legumes had a relatively high abundance in the control and their growth was favoured, especially that of Medicago sativa, by P addition. Grasses' growth was increased by the addition of N. Inhibition of rhizobia resulted in poor growth of legumes and concomitant higher growth of grasses, in comparison to the control. The N:P ratios of non-legume species differed between treatments and were always higher in the legume species, even in the disinfected soil. The latter provides evidence that the high N concentrations found in legumes are a physiological characteristic of this specific group of plants.     

刨花楠不同相对生长速率下林木叶片碳氮磷的适应特征

分别对9年生与13年生刨花楠林木叶片氮磷养分之间关系及林木生物量相对生长速率与叶片碳氮磷化学计量比关系进行分析,探讨不同相对生长速率下的林木叶片N、P养分适应特征,并检验相对生长速率假说理论对刨花楠树种的适应性。结果表明:两种年龄刨花楠林木生物量相对生长速率、叶片C、N、P含量及其计量比值均存在显著差异;同一年龄的林木叶片N、P之间存在显著相关性,二者具有协同相关性;9年生林木叶片P含量及C∶P、N∶P与生物量相对生长速率呈二次曲线相关,而13年生林木叶片N、P含量及C∶N、C∶P、N∶P则与生物量相对生长速率均呈线性相关。研究表明,在能满足植物生长所需养分供给的土壤环境中,叶片N、P含量与林木相对生长速率间呈线性正相关,但当土壤中养分供应满足不了植物高速生长时,植物则会对有限的养分资源进行适应性调整。     

放牧对内蒙古锡林河流域草地群落植物茎叶生物量资源分配的影响

以内蒙古锡林河流域沿水分梯度分布的灰脉苔草(Carex appendiculata)、贝加尔针茅(Stipa baicalensis)、羊草(Leymus chinensis)、大针茅(Stipa grandis)、小叶锦鸡儿(Caragana microphylla)和冷蒿(Artemisia frigida) 6个草地群落为对象, 研究了围封禁牧与放牧样地中144个共有植物种的高度、丛幅面积、茎、叶和株(丛)生物量、茎叶比等性状。结果表明: 1)在个体水平上, 放牧样地中植物的生殖枝高度、营养枝高度、丛幅面积、单株(丛)生物量、茎、叶生物量和茎叶比均显著低于围封禁牧样地, 植物在放牧干扰下表现出明显的小型化现象; 2)在群落水平上, 放牧亦显著降低了群落总生物量和茎、叶生物量; 3)过度放牧显著改变了物种的资源分配策略, 使生物量向叶的分配比例增加, 向茎的分配比例减少。资源优先向同化器官分配可能是植物对长期放牧干扰的一种重要适应对策; 4)轻度放牧对物种的资源分配没有显著影响, 单株(丛)生物量和群落茎、叶及总生物量均表现出增加趋势, 这与过度放牧的影响正好相反。过度放牧引起的植物个体小型化改变了生态系统中物种的资源分配策略, 进而对生态系统功能产生重要的影响。