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1.
三江平原湿地小叶章群落磷素积累动态与生物量动态分析 总被引:3,自引:4,他引:3
采用野外定位观测结合室内分析的方法,对三江平原典型小叶章湿地两种类型小叶章生长季磷的积累及植物生物量的季节动态进行研究,以揭示三江平原湿地中磷在植物中积累的季节动态变化及其与植物生物量积累之间的关系,进一步认识磷在湿地系统中通过植物吸收迁移转化的机制。结果表明,两种小叶章群落地上、地下生物量以及植物体磷储量有明显的季节动态变化,但二者季节变化特征不同。此外,植物体地上、地下部分磷素积累量和生物量在整个植物体所占的比重两种类型也存在一定差异,这与植物所处的生境及其生态适应有一定关系。分析两种小叶章群落的生长速率(AGR)以及磷素的积累速率(Vp),表明在生长初期,磷是植物生长的重要营养元素。两种小叶章的AGR、Vp的变化曲线相似,说明对于这两种小叶章群落,生境不是磷积累速率的主要影响因素。 相似文献
2.
三江平原典型小叶章湿地土壤氮素净矿化与硝化作用 总被引:4,自引:2,他引:4
2004年6月—2005年7月,利用PVC顶盖原位培育法研究了三江平原典型草甸小叶章湿地和沼泽化草甸小叶章湿地土壤(0~15cm)无机氮库、净矿化/硝化速率动态、影响因素及年净矿化/硝化量.结果表明:两种湿地土壤的无机氮均呈明显的动态变化特征,其NH4 -N、NO3-N含量均表现为典型草甸小叶章湿地>沼泽化草甸小叶章湿地.两种湿地土壤的净矿化/硝化速率均呈明显的波动变化,生物固持作用、反硝化作用以及雨季较多降水是导致净矿化/硝化速率出现负值的主要原因.温度、降水、土壤有机质含量、C/N和pH是引起二者土壤无机氮库、净矿化/硝化速率存在明显差异的重要原因.典型草甸小叶章湿地的年净矿化量(19.41kg·hm-2)、年净硝化量(4.27kg·hm-2)以及净硝化量占净矿化量的百分比(22.00%)明显高于沼泽化草甸小叶章湿地(5.51kg·hm-2、0.28kg·hm-2和5.08%),说明前者的氮有效性以及维持可利用氮的能力明显高于后者. 相似文献
3.
三江平原小叶章湿地生态系统硫的生物地球化学循环 总被引:3,自引:0,他引:3
以三江平原小叶章湿地生态系统为研究对象,应用分室模型研究了硫在大气-土壤-植物系统各分室中的分布及循环过程。结果表明,在植物-土壤系统内,土壤是主要的贮存库和流通介质,有97.78%的硫贮存在土壤中,且主要以有机硫的形态存在,2.22%的硫贮存在植物中。在植物亚系统中,根是主要的贮库,79.60%的硫贮存在根中。湿地植物地上部分吸收的总S量为0.75gS/m^2;向地下再转移的总S量为0.24gS/m^2,向枯落物S库转移的总S量为0.51gS/m^2;根吸收的总S量为3.76gS/m^2;根向土壤S库转移的总S量为3.07gS/m^2;现存枯落物中的总S量为0.75gS/m^2;枯落物向土壤S库的转移量最低为0.52gS/m^2·a。输入和输出过程的研究表明,小叶章湿地生态系统在生长季(5-9月份)向大气排放H2S的量为1.42mgS/m^2,从大气吸收COS的量为1.83mgS/m^2;通过大气降水输入到生态系统中的硫为4.85mgS/m^2,其差值为5.26mgS/m^2,这表明硫在小叶章湿地生态系统中处于累积状态,湿地存在潜在的酸化趋势。 相似文献
4.
三江平原小叶章模拟实验对氮磷的净化 总被引:8,自引:0,他引:8
模拟研究三江平原小叶章湿地生态系统对N、P的净化规律。结果表明,在小叶章生长期和成熟期,模拟系统对N、P的去除率随时间变化呈负指数型增长,最高去除率在实验初期分别达到93.26%、98.98%;在净化过程中,P的加入会促进模拟系统对N的吸收,并减缓其对N净化能力的衰退幅度,而模拟系统对P的净化不受N输入的影响。基于小叶章生态系统中N、P营养元素的分配和循环,小叶章对N元素的净化效应大于P元素,土壤子系统对P元素的净化起主导作用,整个模拟系统对N、P元素的净化效果很显著,总净化率分别可达53.11%、58.95%。该结果为东北地区湿地净化功能的研究和非点源污染的治理提供理论根据。 相似文献
5.
三江平原典型草甸小叶章种群地上生物量动态 总被引:17,自引:0,他引:17
本文在东北三江平原典型草甸小叶章种群地上生物量及其组成动态关系的研究结果表明,小叶章种群地上生物量及其组成部分茎,叶,穗生物量季节动态的呈单峰型,在7月末达到极大值,分别为99.695,571.48,411.58,13.89g/M^2抛物线拟合效果良好,且相互间存在明显的线性关系,直线拟合效果良好,F/C〈1,说明其生产效率较典型草原低,而高于同地区的芦苇种各及陕北黄土高原的禾草群落,F/C值和结 相似文献
6.
三江平原典型小叶章湿地土壤氨挥发特征及影响因素 总被引:4,自引:0,他引:4
采用通气法对三江平原典型草甸小叶章湿地和沼泽化草甸小叶章湿地土壤的氨挥发进行了原位测定,并对其主要影响因素进行了分析。结果表明,二者的氨挥发速率在生长季内的变化趋势基本一致,7月中旬前出现两次挥发高峰和一次低值,之后整体呈严格单调下降趋势,后者的氨挥发速率较高,平均为前者的1.35±0.53倍;二者累计氨挥发量的变化趋势也基本一致,7月中旬前增加迅速,且值比较接近;之后增加缓慢,但其值发生明显分异,表现为后者大于前者;生长季内,典型草甸小叶章湿地土壤的氨挥发总量为6.35 kg N.hm-2,而沼泽化草甸小叶章湿地则为6.87 kg N.hm-2,二者之比为1∶1.08;氮素物质基础不是影响二者氨挥发过程的重要限制因素,大气温度及其所引起的其它温度波动是影响氨挥发速率变化的重要因素;降水及土壤水分波动与散失是引起氨挥发速率局部波动的重要原因;土壤pH和质地是导致氨挥发速率普遍较低的根本原因;而各种因素综合作用的结果则是引起二者氨挥发速率和氨挥发量变化及差异的主要原因。 相似文献
7.
三江平原湿地典型植物群落物种多样性研究 总被引:16,自引:1,他引:16
以三江平原分布最广的毛果苔草(Carex lasiocarpa)群落和小叶章(Calamagrostis angustifolia)群落为研究对象,研究2个群落的植物物种及其组成特征。结果表明,毛果苔草群落以毛果苔草为优势种,以漂筏苔草(C.pseudocuraica)为亚优势种,二者的重要值之和为56.4%;小叶章群落以小叶章为优势种,其重要值为50.8%。物种多样性分析表明,毛果苔草群落和小叶章群落的Simpson指数(D)、Shannon-Wiener指数(H)和Pielou均匀度指数(J)均有较大波动,且H与J呈显著正相关,与D呈显著负相关,与S无显著相关关系;毛果苔草群落的H、D、J和S均高于小叶章群落,但差异不显著;2群落的相似性指数为46.5%,表明二者间存在一定的联系。 相似文献
8.
以三江平原湿地代表植物小叶章为对象,通过对杂类草草甸、典型草甸、沼泽化草甸、沼泽生境中小叶章个体大小与生物量差异及繁殖构件与植株生物量之间相关关系的分析,研究不同生境中水位对小叶章个体生物量与繁殖分配的影响。结果表明: 小叶章个体大小、高度及有性繁殖特征随水位升高而显著降低;杂类草草甸、典型草甸、沼泽化草甸和沼泽中小叶章的繁殖阈值分别为0.245、0.149、0.148和0.157 g;除沼泽化草甸外,其他3种生境中小叶章植株个体大小与繁殖分配均呈显著负相关;相较于个体大小,土壤含水量对于小叶章有性繁殖分配影响更大,不同生境中小叶章对个体大小和繁殖分配的差异投资是其具有良好生态适应性的基础条件。 相似文献
9.
三江平原小叶章湿地枯落物分解及主要元素变化动态 总被引:5,自引:1,他引:5
应用分解袋法研究了三江平原小叶章湿地枯落物的分解失重及其主要营养元素的变化动态。结果表明,小叶章枯落物的年分解速率为0.257,二次指数模型:Wt/W0=0.0399e-0.545t+0.9601e0.018t(R2=0.945)能更好地描述其分解失重动态。分解过程中,C、N、P、Ca的积累系数(NAI)<100%(P<0.05),元素发生了净释放;K、Na的NAI>100%(P<0.05),元素发生了净积累;Mg、Mn、Fe的NAI值与100%无显著差异(P>0.05),元素既有释放又有积累。分解16个月后,小叶章枯落物各元素总体释放率的大小顺序为:Fe>P>Ca>N>C>Mg>Mn>K>Na,而相应元素的释放量分别为:0.106、0.147、0.971、0.568、65.37、-0.017、-0.114、-0.209和-0.125 g.m-2。 相似文献
10.
利用开顶箱薰气室,设置正常大气CO2浓度(350 μmol·mol-1)、高CO2浓度(700 μmol·mol-1)2个CO2水平和不施氮(0 g N·m-2)、中氮(5 g N·m-2)和高氮(15 g N·m-2)3个氮素水平,研究CO2浓度升高和氮肥施用对三江平原草甸小叶章生长的影响.结果表明:随着CO2浓度升高,小叶章物候期提前,其中抽穗期提前1~2 d,成熟期提前3 d;不施氮、中氮和高氮水平下, CO2浓度升高使小叶章的分蘖分别增加8.2%(P<0.05)、8.4%(P<0.05)和5.5%(P>0.05);在小叶章生长初期,CO2浓度升高对其生物量的增加有促进作用,拔节期和抽穗期小叶章地上生物量分别增加12.4%和20.9%(P<0.05);生长后期则对小叶章地下生物量的促进作用增大,腊熟期和成熟期的地下生物量分别增加20.5%和20.9% (P<0.05).小叶章生物量对高浓度CO2的响应与供氮水平有关,供氮充足条件下, 高浓度CO2对生物量的促进效应更大. 相似文献
11.
To better understand the Sulfur (S) cycle in the wetland ecosystem, the S cycle and its compartmental distribution within an atmosphere-plant-soil system were studied using a compartment model in the Calamagrostis angustifolia wetland in the Sanjiang Plain, Northeast China. The results showed that the soil was the main S storage and flux hinge in which 97.78% S was accumulated. In the plant subsystem, the root was the main S storage, and it remained at 79.60% of the total S contents, which in the Calamagrostis angustifolia wetland ecosystem showed that the parts above the ground took up 0.75 g S/m2, the S re-transferring biomass to the root was 0.24 g S/m2, and to the litter was 0.51 g S/m2; the root took up 3.76 g S/m2 and the S transferring biomass to the soil took up 3.07 g S/m2; the litter S biomass was 0.75 g S/(m2·a) and the S transferring biomass to the soil was more than 0.52 g S/(m2·a). The emission amount of H2S from the Calamagrostis angustifolia wetland ecosystem to the atmosphere was 1.42 mg S/m2, whereas carbonyl sulfide (COS) was absorbed by the Calamagrostis angustifolia wetland from the atmosphere and the absorption amount was 1.83 mg S/m2. The S input biomass from the rain to the ecosystem was 4.85mg S/m2 during the growing season. The difference between input and output amounts was 5.26 mg S/m2, which indicated that S was accumulated in the ecosystem and would lead to wetland acidification in the future. 相似文献
12.
Distribution and fate of anthropogenic nitrogen in the Calamagrostis angustifolia wetland ecosystem of Sanjiang Plain, Northeast China 总被引:1,自引:0,他引:1
Wetlands are important for the protection of water quality of rivers and lakes, especially those adjacent to agricultural landscapes, by intercepting and removing nutrients in runoff. In this study, the 15N tracer technique was applied to study the distribution and fate of anthropogenic nitrogen (15N-fertilizer) in Calamagrostis angustifolia Kom wetland plant-soil microcosms to identify the main ecological effects of it. 15NH415NO3 solution (14.93 mg N/L, 20.28 at.% 15N) was added to each microcosm of the first group, which was approximate to the current nitrogen concentration (CNC) of farm drainage, and 29.86 mg NIL 15NH415NO3 solution was added to another group, which was approximate to the double nitrogen concentration (DNC) of farm drainage, while no nitrogen (NN) was added to the third group. The results suggest that the Input of anthropogenic nitrogen has positive effects on the biomass and total nitrogen content of plant, and the positive effects will be elevated as the increase of its Input amount. The increase of 15N-fartilizer can also elevate its amounts and proportions in plant nitrogen. Soil nitrogen is still the main source of plant nitrogen, but its proportion will be reduced as the increase of 15N-fertilizer. The study of the fate of 15N-fartilizar indicates that, in CNC treatment, only a small proportion is water-dissolved (0.13±0.20%), a considerable proportion is soil-immobilized (17.02±8.62%), or plant-assimilated (23.70±0.92%), and most is lost by gaseous forms (59.15±8.35%). While in DNC treatment, about 0.09±0.15% is water-dissolved, 15.33±7.46% is soil-immobilized, 23.55±2.86% is plant-assimilated, and 61.01±5.59% is lost by gaseous forms. The double input of anthropogenic nitrogen can not elevate the proportions of plant-assimilation, soil-immobilization and water-dissolution,but it can enhance the gaseous losses. 相似文献
13.
三江平原湿地土壤磷形态转化动态 总被引:7,自引:2,他引:7
采用Hedley连续浸提法对三江平原湿地小叶章草甸土壤磷形态的季节动态进行研究,分析生长季土壤磷形态之间的相互转化及其可能的驱动机制。结果表明:小叶章草甸土壤有机磷(TPo)总量高于无机磷(TPi),NaOH溶液浸提的无机磷(NaOH-Pi)和有机磷形态(NaOH-Po)分别占总无机磷(TPi)和总有机磷(TPo)比重最大。各无机磷形态均有明显的季节变化,Resin-P和Conc.HCl-Pi季节变异性大,生长结束后含量较初期降低,其他形态无机磷含量有不同程度的升高。有机磷组分中NaOH-Po的季节波动最明显,生长季末期较初期含量降低,其他有机磷形态和Residual-P生长季初、末期含量变化不大,波动也相对较小。TP、TPo季节变化整体趋势相似,二者含量变化达到极显著相关。各无机磷形态变化主要受植物生长节律影响;水分、热量等环境条件也是磷的形态转化的重要驱动因子,并可能间接通过影响土壤动物、微生物等的活性推动土壤磷的循环。小叶章草甸土壤有机磷矿化释放的无机磷通常都首先被土壤金属氧化物固定,再经过无机磷之间的转化过程为生物利用,因此三江平原湿地土壤磷大量释放的可能性很小。 相似文献
14.
利用开顶箱薰气室,设置正常大气CO2浓度(350 μmol·mol-1)、高CO2浓度(700 μmol·mol-1)2个CO2水平和不施氮(0 g N·m-2)、中氮(5 g N·m-2)和高氮(15 g N·m-2)3个氮素水平,研究CO2浓度升高和氮肥施用对三江平原草甸小叶章生长的影响.结果表明:随着CO2浓度升高,小叶章物候期提前,其中抽穗期提前1~2 d,成熟期提前3 d;不施氮、中氮和高氮水平下, CO2浓度升高使小叶章的分蘖分别增加8.2%(P<0.05)、8.4%(P<0.05)和5.5%(P>0.05);在小叶章生长初期,CO2浓度升高对其生物量的增加有促进作用,拔节期和抽穗期小叶章地上生物量分别增加12.4%和20.9%(P<0.05);生长后期则对小叶章地下生物量的促进作用增大,腊熟期和成熟期的地下生物量分别增加20.5%和20.9% (P<0.05).小叶章生物量对高浓度CO2的响应与供氮水平有关,供氮充足条件下, 高浓度CO2对生物量的促进效应更大. 相似文献
15.
Biogeochemical cycle of Sulfer in the Calamagrostis angustifolia wetland ecosystem in the Sanjiang Plain, China 
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下载免费PDF全文 To better understand the Sulfur (S) cycle in the wetland ecosystem, the S cycle and its compartmental distribution within an atmosphere-plant-soil system were studied using a compartment model in the Calamagrostis angustifolia wetland in the Sanjiang Plain, Northeast China. The results showed that the soil was the main S storage and flux hinge in which 97.78% S was accumulated. In the plant subsystem, the root was the main S storage, and it remained at 79.60% of the total S contents, which in the Calamagrostis angustifolia wetland ecosystem showed that the parts above the ground took up 0.75 g S/m2, the S re-transferring biomass to the root was 0.24 g S/m2, and to the litter was 0.51 g S/m2; the root took up 3.76 g S/m2 and the S transferring biomass to the soil took up 3.07 g S/m2; the litter S biomass was 0.75 g S/(m2·a) and the S transferring biomass to the soil was more than 0.52 g S/(m2·a). The emission amount of H2S from the Calamagrostis angustifolia wetland ecosystem to the atmosphere was 1.42 mg S/m2, whereas carbonyl sulfide (COS) was absorbed by the Calamagrostis angustifolia wetland from the atmosphere and the absorption amount was 1.83 mg S/m2. The S input biomass from the rain to the ecosystem was 4.85mg S/m2 during the growing season. The difference between input and output amounts was 5.26 mg S/m2, which indicated that S was accumulated in the ecosystem and would lead to wetland acidification in the future. 相似文献
16.
两种水分生态型小叶章的生理生态特征研究 总被引:1,自引:1,他引:1
通过野外调查与控制试验相结合的方法,比较研究了两种水分生态型小叶章的生理生态特征,结果表明:(1)自然条件下,小叶章沼泽化草甸群落Simpson多样性指数显著高于小叶章草甸群落,但是小叶章草甸群落中小叶章种群生物量显著高于沼泽化草甸群落;草甸小叶章的株高、节长、叶长、叶宽及叶绿素含量均显著高于沼泽化草甸小叶章;叶片干重和叶鞘干、鲜重以及叶片与叶鞘生物量分配比为沼泽化草甸小叶章较高,而茎的干、鲜重和叶片鲜重、总地上生物量及茎生物量分配比均为草甸小叶章较高,但差异均不显著.(2)在人工控制水位条件下,两种生态型小叶章种群密度差异显著,而种群高度则无显著差异;两种生态型小叶章在0 cm、20 cm水位梯度下的叶长,30 cm水位梯度下的叶宽,以及0 cm水位梯度下的叶面积均存在显著差异,沼泽化草甸小叶章个体生长指标均对水位梯度具有显著响应,而典型草甸小叶章仅叶绿素含量对水位梯度具有显著响应.研究发现,两种生态型小叶章对水位条件的敏感程度不同,不同条件下对水位梯度具有不同的响应规律. 相似文献