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1.
磷是植物所需主要营养元素之一,对植物生长和繁殖起关键作用,也影响着池塘生态系统的全局稳定性.因此定量分析池塘生态系统中磷循环的内在机理,科学调控池塘生态系统中的磷循环具有重要的意义.本文依据磷循环过程的特征以及池塘生态系统的结构特点,利用传染病模型的理论,建立磷循环的动力学模型.通过求解方程组的正平衡点与阈值,分析影响磷循环的可控因子和可控范围及循环特征条件,再利用Hurwitz定理证明平衡点处的渐近稳定性,分析池塘生态系统的稳定性,为磷循环的开发利用提出科学建议.最后,通过仿真验证了理论分析的结果.  相似文献   

2.
农业生态系统中磷循环的研究进展   总被引:6,自引:2,他引:4  
1 引 言能量转化和物质循环是农业生态系统最基本的功能特征。1976年在荷兰召开的第一次农业生态系统矿质养分循环研讨会标志着从系统层次研究物流的开始,但物流仍是系统研究的薄弱环节,特别是较高系统层次准确的物流的数量概念更为缺乏[1,2]。生态系统中营养元素的输入、输出状况反映了一个地区生产发展水平的高低和生态系统功能的强弱;而投入、产出的动态变化,则显示了一定时期内营养元素循环的基本规律[3]。在各种水平(如地球、陆地、国家或生态系统)上的有关磷循环的论文也发表了不少,借以阐述各组成部分中磷的数量及其相互间的转化速…  相似文献   

3.
硅是环境中最为常见的元素之一,在地壳中的丰度为28.8%,是多数植物生长的有益元素。在生态系统中,硅循环与碳和营养元素的循环密切相关。以往国内外对于硅循环的研究大多针对海洋和陆地生态系统,而湖泊-流域系统中硅的循环过程及其对碳和营养元素循环影响的研究尚且不多。本文结合国内外研究进展,综述硅在湖泊-流域系统的存在形态及分布,阐述硅在湖泊-流域系统中的基本循环过程,以及该循环过程对碳和养分循环的影响及其作用机制。在此基础上,提出了今后的研究工作应对湖泊硅素来源进行分析,并确定湖泊沉积物中植硅体与硅藻固碳量,同时完善湖泊氮、磷、硅含量及其生态化学计量关系,最后建立湖泊-流域系统硅-碳-养分耦合循环模型。本文有助于更好地了解湖泊-流域系统硅循环过程以及硅循环对碳、养分循环的影响机制,为缓解湖泊-流域水体富营养化现象和全球气候变化提供科学参考。  相似文献   

4.
植物在湿地养分循环中的作用   总被引:2,自引:0,他引:2  
郭雪莲  吕宪国  郗敏 《生态学杂志》2007,26(10):1628-1633
植物是湿地生态系统的重要组成部分之一,在养分循环过程中起着重要的作用。植物通过自身的生长代谢吸收湿地中的营养元素,但植物对营养物质的吸收能力随植物种类、群落组成及季节不同而存在差异;不同植物以及植物的不同器官对营养元素的累积特征存在显著差异,并随生长节律表现出明显的季节动态;植物本身的化学组成和特征制约着枯落物的分解和矿化过程,从而影响植物的养分归还。本文从植物对湿地营养元素吸收、累积以及养分归还方面总结了植物在湿地养分循环中的作用,指出目前研究中存在的不足,并对今后的研究提出一些建议。  相似文献   

5.
江苏省太湖地区养分循环平衡状况的初步探讨   总被引:7,自引:0,他引:7  
农业生产的本质是物质循环和能量转化的过程。人类要想合理地利用自然,获得高产、优质、低消耗的农业生态结构,必须进行物质循环和能量转化的研究。关于物质循环的研究国外开展较早。通过农田养分收支平衡的估算,为改进施肥措施和进行合理的作物布局提供了科学依据,取得了较好效果。1976年,在荷兰Amsterdam首次召开了农田生态系统中矿质营养元素循环的国际会议,会上发表了65个国家或地区不同类型农业生态系统中养分循环平衡的文章。这方面的研究工作目前正在不断深入中。  相似文献   

6.
亚热带侵蚀红壤植被恢复后营养元素通量的变化   总被引:8,自引:1,他引:7  
谢锦升  杨玉盛  陈光水  高人 《生态学报》2005,25(9):2312-2319
对亚热带花岗岩红壤强度侵蚀地采取种草促林(ER1)、植灌促林(ER2),栽阔促林(ER3)3种生态恢复措施近20a后生态系统的营养元素储量及通量进行了研究,并以强度侵蚀地(CK1)和村旁受保护的风水林(CK2)为对照。研究结果表明:强度侵蚀地生态系统储存在植被中的营养元素总量及流通量极小,植被营养元素库存量仅7.494kg/hm2,乔木层营养元素年吸收量0.505kg/hm2,年归还量0.141kg/hm2。生态恢复约20a后,植被养分库储量和通量显著增加,ER1、ER2和ER3植被的营养元素总储量分别是强度侵蚀地的22.2、99.5倍和62.3倍,乔木层营养元素年吸收量分别是强度侵蚀地的20.9、171.5倍和82.9倍,年归还量分别是强度侵蚀地的42.5、158.4倍和93.9倍,年存留量分别是强度侵蚀地的12.5、176.6倍和78.7倍。ER2的营养元素循环恢复程度最好,虽然其植被营养元素库储存量、吸收量和归还量仍低于同地带未遭侵蚀的马尾松林,但其营养元素的吸收量和存留量与CK2的已没有显著差异,生态系统已基本具有自我维持功能。而施肥、有效的水土保持工程措施、种植当地适生的固N树种、适当高的密度、加强植被管理等措施,均可能有利于营养元素循环功能的恢复。  相似文献   

7.
森林生态系统中的养分循环是该系统的主要功能之一 ,历来为许多研究者所重视[1,4 ,5] 。磷是植物生长发育所不可缺少的重要营养元素 ,它对促进林木生长 ,提高林业生产力具有很大作用。以往有关森林生态系统磷素循环的研究 ,大多忽视了根系凋落归还的作用 ,从而影响循环结果及其相应评价。为此 ,研究了苏南丘陵次生栎林生态系统磷素循环 ,并进行系统分析 ,建立生态系统磷素动态模型 ,预测并分析其变化规律 ,为制定合理的经营管理措施 ,保持林业持续发展提供理论依据。1 自然概况与研究方法1.1 自然概况试验地位于江苏省句容县境内 ,东经119…  相似文献   

8.
养分循环是森林生态系统的重要生态功能。以位于青藏高原东南缘的川西折多山东坡川滇高山栎(Quercus aquifolioides)灌丛为研究对象,分析了其营养元素的分布、积累和生物循环特征。结果显示:(1)川滇高山栎不同器官营养元素含量不同,叶片和枝条为NKCaMgP,树干和地下器官为CaKNMgP。(2)川滇高山栎灌丛生态系统各营养元素总贮量(kg/hm2)依次为:Ca(650.06)、N(252.67)、K(197.01)、Mg(51.18)、P(49.22),其中川滇高山栎灌层储量占88.61%~96.10%,林下草本层占0.64%~4.22%,凋落物层占2.54%~9.25%。(3)川滇高山栎灌层营养元素主要储存于地下根系,占灌层的67%~81%,丰富的根系营养元素储量有利于川滇高山栎灌丛在遭受火烧、砍伐等干扰后萌生更新。(4)川滇高山栎灌丛营养元素年积累量[kg/(hm2·a)]依次为:Ca(20.82)、N(7.46)、K(6.12)、P(2.33)、Mg(1.55);灌丛营养元素利用系数为0.09,循环系数为0.60,周转时间为22.87a。研究表明,川滇高山栎灌丛具有较低的营养元素利用率和较长的营养元素周转期。  相似文献   

9.
丛枝菌根真菌在土壤氮素循环中的作用   总被引:12,自引:0,他引:12  
陈永亮  陈保冬  刘蕾  胡亚军  徐天乐  张莘 《生态学报》2014,34(17):4807-4815
作为植物需求量最大的营养元素,氮素是陆地生态系统初级生产力的主要限制因子。丛枝菌根真菌能与地球上80%以上的陆生植物形成菌根共生体,帮助宿主植物吸收土壤中的P、N等矿质养分。目前,丛枝菌根真菌与氮素循环相关研究侧重于真菌对氮素的吸收形态以及共生体中氮的传输代谢机制,却忽略了丛枝菌根真菌在固氮过程、矿化与吸收过程、硝化过程、反硝化过程以及氮素淋洗过程等土壤氮素循环过程中所起到的潜在作用,并且越来越多的证据也表明丛枝菌根真菌是影响土壤氮素循环过程的重要因子。总结了丛枝菌根真菌可利用的氮素形态及真菌的氮代谢转运相关基因的研究现状;重点分析了丛枝菌根真菌在调控土壤氮素循环过程中的潜在作用以及在生态系统中的重要生态学意义,同时提出了丛枝菌根真菌在土壤氮素循环过程中一些需要深入研究的问题。  相似文献   

10.
长江河口九段沙互花米草湿地生态系统N、P、K的循环特征   总被引:5,自引:0,他引:5  
研究了九段沙外来入侵种互花米草(Spartina alterniflora)湿地生态系统的营养元素含量、分布规律与循环特征。结果表明,九段沙的上沙、中沙和下沙互花米草湿地土壤全量养分含量差异相对较小,而速效性养分含量差异相对较大。土壤剖面中TK含量大大高于TN和TP含量,排序为:TK>TN>TP。各沙洲速效性养分含量排序为:速效K>速效N>速效P。土壤速效性养分与全量养分的空间分布规律并不一致,土壤剖面营养元素的垂直分布差异比较明显,速效性养分土壤剖面垂直分异比全量养分显著。各深度土壤营养元素含量均存在差异,不同沙洲同一深度土壤营养元素含量也存在差异。各沙洲不同深度土壤TN含量的差异明显大于TP和TK含量差异。植物中3种营养元素含量以K最高,N其次,P最低。湿地生态系统营养元素归还量远大于存留量。吸收系数排序为:N>P>K。不同沙洲营养元素的利用系数和循环系数存在明显差异,上沙P元素、中沙与下沙K元素利用系数最大,上沙K元素、中沙P元素与下沙N元素循环系数最大。  相似文献   

11.
The White Sands National Monument from New Mexico (U.S.A) contains one of the largest known gypsum dune fields with unique, rapidly migrating, arid, evaporitic habitats. Deposits from dune sides and interdune areas were collected in order to determine the characteristics of microbial habitat and communities through mineral assemblages, microbial pigments along with investigations of nitrogen and sulfur cycles. The most abundant pigments, scytonemin and carotenoids, were common UV protective pigments. Predominance of nitrite and nitrate over ammonium nitrogen (2.16: 1) implies that nitrification processes might be important in this ecosystem. Ammonium oxidizers from groups of β-, γ-proteobacteria and archaea were detected in all deposits, thereby indicating microbial involvement in nitrification. Additionally, denitrifying organisms with nirS and nirK genes were also present in most of the analyzed samples. The presence of trace carbonate mineral phases in association with biofilm implies possible microbial sulfate reduction. Microbes with metabolic abilities for sulfur cycling (i.e., dissimilatory sulfite reducers, purple sulfur bacteria, green sulfur and non-sulfur bacteria, and organisms with the APS enzyme) were identified in all samples. These particular organisms have the ability to reduce sulfate and to re-oxidize reduced sulfur compounds back to sulfate.  相似文献   

12.

Background

According to the Intergovernmental Panel on Climate Change (IPCC) 2007, natural wetlands contribute 20–39 % to the global emission of methane. The range in the estimated percentage of the contribution of these systems to the total release of this greenhouse gas is large due to differences in the nature of the emitting vegetation including the soil microbiota that interfere with the production and consumption of methane.

Scope

Methane is a dominant end-product of anaerobic mineralization processes. When all electron acceptors except carbon dioxide are used by the microbial community, methanogenesis is the ultimate pathway to mineralize organic carbon compounds. Emergent wetland plants play an important role in the emission of methane to the atmosphere. They produce the carbon necessary for the production of methane, but also facilitate the release of methane by the possession of a system of interconnected internal gas lacunas. Aquatic macrophytes are commonly adapted to oxygen-limited conditions as they prevail in flooded or waterlogged soils. By this system, oxygen is transported to the underground parts of the plants. Part of the oxygen transported downwards is released in the root zone, where it sustains a number of beneficial oxidation processes. Through the pores from which oxygen escapes from the plant into the root zone, methane can enter the plant aerenchyma system and subsequently be emitted into the atmosphere. Part of the oxygen released into the root zone can be used to oxidize methane before it enters the atmosphere. However, the oxygen can also be used to regenerate alternative electron acceptors. The continuous supply of alternative electron acceptors will diminish the role of methanogenesis in the anaerobic mineralization processes in the root zone and therefore repress the production and emission of methane. The role of alternative element cycles in the inhibition of methanogenesis is discussed.

Conclusions

The role of the nitrogen cycle in repression of methane production is probably low. In contrast to wetlands particularly created for the purification of nitrogen-rich waste waters, concentrations of inorganic nitrogen compounds are low in the root zones in the growing season due to the nitrogen-consuming behaviour of the plant. Therefore, nitrate hardly competes with other electron acceptors for reduced organic compounds, and repression of methane oxidation by the presence of higher levels of ammonium will not be the case. The role of the iron cycle is likely to be important with respect to the repression of methane production and oxidation. Iron-reducing and iron-oxidizing bacteria are ubiquitous in the rhizosphere of wetland plants. The cycling of iron will be largely dependent on the size of the oxygen release in the root zone, which is likely to be different between different wetland plant species. The role of the sulfur cycle in repression of methane production is important in marine, sulfate-rich ecosystems, but might also play a role in freshwater systems where sufficient sulfate is available. Sulfate-reducing bacteria are omnipresent in freshwater ecosystems, but do not always react immediately to the supply of fresh sulfate. Hence, their role in the repression of methanogenesis is still to be proven in freshwater marshes.  相似文献   

13.
光降解在凋落物分解中的作用   总被引:2,自引:0,他引:2  
近年来,越来越多的研究者认识到光降解可能在凋落物分解中发挥着重要作用.本文对光降解的作用机制,光降解在碳循环、养分循环中的作用,光降解与微生物分解的关系,以及影响光降解的因素进行了综述.光降解对凋落物分解过程同时具有正效应和负效应,正效应指光降解通过氧化有机质,或是改变凋落物自身理化性质使其更易淋溶和分解,负效应指高光辐射对分解者产生不利影响从而押制微生物分解.在光降解过程中光化学矿化产生CO2是生态系统碳流失的主要机制.除紫外光外,可见光中的蓝、绿光波段也对凋落物的降解产生影响.光降解作用的大小受到水分状况、凋落物化学性质和凋落物的暴露面积的影响.最后,讨论了该领域有待深入研究的方向,指出今后应当重点对光降解研究方法,光降解与环境因子的交互作用,光降解作用的空间差异,光降解与微生物分解的相互关系及其作用强度进行研究.  相似文献   

14.
Deforestation in the Brazilian Amazon has resulted in the conversion of >230,000 km2 of tropical forest, yet little is known on the quantities of biomass consumed or the losses of nutrients from the ecosystem. We quantified the above-ground biomass, nutrient pools and the effects of biomass burning in four slashed primary tropical moist forests in the Brazilian Amazon. Total above-ground biomass (TAGB) ranged from 292 Mg ha-1 to 436 Mg ha-1. Coarse wood debris (>20.5 cm diameter) was the dominant fuel component. However, structure of the four sites were variable. Coarse wood debris comprised from 44% to 69% of the TAGB, while the forest floor (litter and rootmat) comprised from 3.7 to 8.0% of the TAGB. Total biomass consumption ranged from 42% to 57%. Fires resulted in the consumption of >99% of the litter and rootmat, yet <50% of the coarse wood debirs. Dramatic losses in C, N, and S were quantified. Lesser quantities of P, K, and Ca were lost by combustion processes. Carbon losses from the ecosystem were 58–112 Mg ha-1. Nitrogen losses ranged from 817 to 1605 kg ha-1 and S losses ranged from 92 to 122 kg ha-1. This represents losses that are as high as 56%, 68%, and 49% of the total above-ground pools of these nutrients, respectively. Losses of P were as high as 20 kg ha-1 or 32% of the above-ground pool. Losses to the atmosphere arising from primary slash fires were variable among sites due to site differences in concentration, fuel biomass, and fuel structure, climatic fluctuations, and anthropogenic influences. Compared to fires in other forest ecosystems, fires in slashed primary tropical evergreen forests result in among the highest total losses of nutrients ever measured. In addition, the proportion of the total nutrient pool lost from slash fires is higher in this ecosystem compared to other ecosystems due to a higher percentage of nutrients stored in above-ground biomass.  相似文献   

15.
Despite being a significant input into soil carbon pools of many high‐latitude ecosystems, little is known about the effects of climate change on the turnover of mycorrhizal fungal necromass. Here, we present results from the first experiment examining the effects of climate change on the long‐term decomposition of mycorrhizal necromass, utilising the Spruce and Peatland Response Under Changing Environments (SPRUCE) experiment. Warming significantly increased necromass decomposition rates but was strongest in normally submerged microsites where warming caused water table drawdown. Necromass chemistry exerted the strongest control on the decomposition, with initial nitrogen content strongly predicting early decay rates (3 months) and initial melanin content determining mass remaining after 2 years. Collectively, our results suggest that as global temperatures rise, variation in species biochemical traits as well as microsites where mycorrhizal necromass is deposited will determine how these important inputs contribute to the belowground storage of carbon in boreal peatlands.  相似文献   

16.
Cycling of Beryllium and Carbon through hillslope soils in Iowa   总被引:1,自引:0,他引:1  
Isotopes of Be and C were used to reconstruct loess accumulation,hillslope evolution, and agricultural modification in soils of western Iowa.While both elements are derived from additions by the atmosphere (via plants inthe case of carbon), the differences in element cycling allow erosional anddepositional processes to be separated from biochemical processing. Based on10Be, loess accumulation likely occurred simultaneously withhillslope degradation. Rates of loess accumulation declined five-fold betweenearly stages (late Pleistocene and early Holocene) and later stages (lateHolocene) of accumulation, but the absolute timing of accumulation requiresindependent dating methods. Based on 14C measurements, plant inputsand decomposition are significant near the surface, but below1–1.5 m carbon inputs are minimal and decompositionisnearly arrested. The amount of carbon below 1.5 m isconstant (0.1%) and is composed of soil organic matter that was buried byloess.Agricultural modification results in a dramatic redistribution of10Be through soil erosion and deposition. By contrast, theredistribution of soil organic matter is masked by the rapid cycling of Cthrough the topsoil as it continually decomposes and is replaced by plantinputs.  相似文献   

17.
Projections of future changes in land carbon (C) storage using biogeochemical models depend on accurately modeling the interactions between the C and nitrogen (N) cycles. Here, we present a framework for analyzing N limitation in global biogeochemical models to explore how C‐N interactions of current models compare to field observations, identify the processes causing model divergence, and identify future observation and experiment needs. We used a set of N‐fertilization simulations from two global biogeochemical models (CLM‐CN and O‐CN) that use different approaches to modeling C‐N interactions. On the global scale, net primary productivity (NPP) in the CLM‐CN model was substantially more responsive to N fertilization than in the O‐CN model. The most striking difference between the two models occurred for humid tropical forests, where the CLM‐CN simulated a 62% increase in NPP at high N addition levels (30 g N m?2 yr?1), while the O‐CN predicted a 2% decrease in NPP due to N fertilization increasing plant respiration more than photosynthesis. Across 35 temperate and boreal forest sites with field N‐fertilization experiments, we show that the CLM‐CN simulated a 46% increase in aboveground NPP in response to N, which exceeded the observed increase of 25%. In contrast, the O‐CN only simulated a 6% increase in aboveground NPP at the N‐fertilization sites. Despite the small response of NPP to N fertilization, the O‐CN model accurately simulated ecosystem retention of N and the fate of added N to vegetation when compared to empirical 15N tracer application studies. In contrast, the CLM‐CN predicted lower total ecosystem N retention and partitioned more losses to volatilization than estimated from observed N budgets of small catchments. These results point to the need for model improvements in both models in order to enhance the accuracy with which global C‐N cycle feedbacks are simulated.  相似文献   

18.
葛晓敏  唐罗忠  王瑞华  李勇  朱玲  贾志远  丁晖 《生态学报》2018,38(14):5120-5131
大气降水是森林生态系统养分输入的主要途径之一,对养分的生物地球化学循环有着重要的意义。对13年生杨树人工林林外雨、树干流、林内雨和地表径流等水文过程中的养分特征进行了调查分析,旨在了解该生态系统的养分输入与输出规律,为杨树人工林可持续经营提供依据。结果表明,从2013年11月至2014年10月,杨树人工林生态系统林外雨量为1154.1 mm,树干流量仅占大气降水量的2.3%,15.4%的大气降水被杨树人工林的冠层截留;林内雨、树干流与大气降水量(林外雨)的动态变化规律相似。各类降水年加权平均pH值表现为林内雨林外雨树干流;各类降水的离子浓度动态变化规律基本一致,即在降水量较小的11月至次年1月份,各阴阳离子的浓度普遍较高,在降水量较大的2—9月份,阴阳离子浓度普遍较低。SO_4~(2-)-S和Ca~(2+)分别是各类降水中的主要阴离子和阳离子;整体上,树干流的离子浓度林内雨大气降水;林内雨是养分输入的主要形式,通过林内雨输入林地较多的养分离子是Ca~(2+)和K~+,分别为70.83 kg hm~(-2)a~(-1)和63.31 kg hm~(-2)a~(-1);地表径流和土壤渗漏是养分输出的主要形式,输出林地较多的离子是Cl~-和Ca~(2+),分别为196.47 kg hm~(-2)a~(-1)和123.09 kg hm~(-2)a~(-1),其次为SO_4~(2-)-S、Mg~(2+)、Na~+、K~+;NH_4~+-N和NO_3~--N的输出量不足输出离子总量的1%。所以,从水文过程看,杨树人工林生态系统无机氮(NH_4~+-N和NO_3~--N)和K~+表现为净积累,净积累量分别为10.9 kg hm~(-2)a~(-1)和56.4 kg hm~(-2)a~(-1),其他离子表现为净损失,其中Cl~-的净损失量达179.8 kg hm~(-2)a~(-1)左右,其他离子损失量50 kg hm~(-2)a~(-1)。  相似文献   

19.
外来植物入侵对土壤生物多样性和生态系统过程的影响   总被引:23,自引:0,他引:23  
随着科学家对生态系统地下部分的重视,评价外来植物入侵对土壤生态系统的影响成为当前入侵生态学领域的研究热点之一。本文综述了外来植物入侵对土壤微生物、土壤动物以及土壤碳、氮循环动态影响的研究,并探讨了其影响机制。已有的研究表明,植物入侵对土壤生物多样性及相关生态系统过程的影响均存在不一致的格局,影响机制也是复杂多样的。外来植物与土著植物凋落物的质与量、根系特征、物候等多种生理生态特性的差异可能是形成格局多样性和影响机制复杂性的最主要原因。今后,加强多尺度和多生态系统的比较研究、机制性研究、生物多样性和生态系统过程的整合性研究及土壤生态系统对植物入侵的反馈研究是评价外来植物入侵对土壤生态系统影响的发展趋势。  相似文献   

20.
Colin Averill 《Ecology letters》2014,17(10):1202-1210
Allocation trade‐offs shape ecological and biogeochemical phenomena at local to global scale. Plant allocation strategies drive major changes in ecosystem carbon cycling. Microbial allocation to enzymes that decompose carbon vs. organic nutrients may similarly affect ecosystem carbon cycling. Current solutions to this allocation problem prioritise stoichiometric tradeoffs implemented in plant ecology. These solutions may not maximise microbial growth and fitness under all conditions, because organic nutrients are also a significant carbon resource for microbes. I created multiple allocation frameworks and simulated microbial growth using a microbial explicit biogeochemical model. I demonstrate that prioritising stoichiometric trade‐offs does not optimise microbial allocation, while exploiting organic nutrients as carbon resources does. Analysis of continental‐scale enzyme data supports the allocation patterns predicted by this framework, and modelling suggests large deviations in soil C loss based on which strategy is implemented. Therefore, understanding microbial allocation strategies will likely improve our understanding of carbon cycling and climate.  相似文献   

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