松嫩平原碱化草地植物－环境系统的仿真模拟

本研究以系统仿真的方法对松嫩平原碱化草地植物－环境系统进行模拟。模型的系统变量包括植物种的地上、地下生物量,土壤水分、有机质、可溶性和交换性Ｎａ￣＋和Ｃａ￣＋＋浓度和植物的凋落物生物量。模型所考虑的过程有：不同土壤碱化条件下的植物生长季节动态;土壤水、盐运动;植物的蒸腾作用;土壤表面的蒸发;凋落物的积累和分解;土壤有机质的积累和矿化;地下生物量对土壤持水和导水特性的控制作用,以及收获强度对系统平衡的影响等。模型成功地解释了植物生物量形成过程与环境之间的动态耦合、相关作用。模拟结果说明：与地下生物量密切相关的土壤非毛管孔隙度与土壤的碱化和脱碱过程有极强的相关作用,这种作用是通过改变土壤的饱和持水量来实现的。非毛管孔隙度随地下生物量增加．导致饱和含水量增加和脱碱作用加强。收获强度过大导致地下生物量的减少、非毛管孔隙度的减少和碱化作用的加强。     

松嫩平原碱化草地植物-环境系统的仿真模拟

 本研究以系统仿真的方法对松嫩平原碱化草地植物—环境系统进行模拟。模型的系统变量包括植物种的地上、地下生物量,土壤水分、有机质。可溶性和交换性Na+和Ca++浓度和植物的凋落物生物量。模型所考虑的过程有：不同土壤碱化条件下的植物生长季节动态;土壤水、盐运动;植物的蒸腾作用;土壤表面的蒸发;凋落物的积累和分解;土壤有机质的积累和矿化;地下生物量对土壤持水和导水特性的控制作用,以及收获强度对系统平衡的影响等。模型成功地解释了植物生物量形成过程与环境之间的动态耦合、相关作用。模拟结果说明：与地下生物量密切相关的土壤非毛管孔隙度与土壤的碱化和脱碱过程有极强的相关作用,这种作用是通过改变土壤的饱和持水量来实现的。非毛管孔隙度随地下生物量增加,导致饱和含水量增加和脱碱作用加强。收获强度过大导致地下生物量的减少、非毛管孔隙度的减少和碱化作用的加强。     

基于光合产物动态分配的玉米生物量模拟

光合产物分配是作物生长发育及生物量形成的关键环节,也是作物生长模拟的重要内容.本研究依据光合产物分配机理,结合玉米不同生长阶段的光合产物分配特点,构建了玉米光合产物分配模型.与WOFOST模型的CO₂同化模块相结合,实现了对玉米各器官生物量动态的逐日模拟.利用锦州农田生态系统野外观测站5年的春玉米大田试验资料对模拟效果进行了验证.结果表明: 模型能解释总生物量变化的95.4%;对营养器官生物量变化的解释率达87.0%;对叶、根、茎生物量变化的解释率分别达85.3%,67.9%和76.5%;对穗生物量变化的解释率达87.5%.模型可实现玉米各器官的生物量动态的准确模拟.     

湿地翅碱蓬生物量遥感估算模型

以黄河三角洲HJ-1A CCD遥感数据和滨海湿地翅碱蓬生物量实测数据为数据源,通过对比分析参数回归模型（单变量线性和非线性回归模型,多元线性逐步回归模型）和人工神经网络模型（BP网络、RBF网络、GRNN网络）,构建黄河三角洲湿地翅碱蓬生长初期的生物量湿重遥感估算最优模型。研究表明：基于遥感信息变量能够建立生长初期翅碱蓬生物量湿重估算模型。尽管基于RDVI、MSAVI和PC2的3个变量的多元线性回归模型的拟合效果较优,但是以SAVI、MSAVI、RVI、DVI、RDVI和PC2等7个遥感信息变量构建的BP神经网络模型的精度更高,平均相对误差为12.73%,估算效果最优,能够满足较高精度的生物量湿重估算需求。翅碱蓬生长初期生物量湿重最优估算模型的建立,为滨海地区植被生物量监测、区域翅碱蓬生物量季节动态模拟以及黄河三角洲生态系统功能评价提供技术支持与基础。     

植物群落动态的模型分析

植物群落的动态是植物群落学的中心问题之一,包括更新、波动、演替、进化等主要内容。空间格局对种群和群落的动态起着至关重要的作用,种群空间格局和群落空间结构是群落中各种过程相互作用的产物。模型是描述群落动态、认识植物群落组建和维持机理的有效工具。本文阐述和比较了描述群落动态的四种具有代表性的经验模型,即镶嵌循环模型、随意游走模型、同资源种团比例模型、空间抢先占有模型及其机理。四种经验模型的空间性及缺陷分别是:(1)“镶嵌循环模型”考虑到了相邻斑块之间的植被空间结合在群落动态中的作用,而另外三种模型没有考虑到这一点;(2)在一定程度上,四种植物群落动态模型对各自针对的植物群落可能是适合的,但要作为描述群落动态发展的一般性模型还需要不断完善和发展;因为四种模型均没有考虑到自然干扰和人类干扰对植物群落动态的影响。作者对将来植物群落动态的研究及实践意义做出以下展望:(1)在不同空间尺度上,更加有效地评价控制群落动态变化的各种过程的相对重要性,并进一步将它们之间的复杂相互作用整合到群落动态模型中;(2)充分认识植物群落中存在的各种自然环境条件和生物群体的结构配置对植物群落动态发展的重要性;(3)重视植物群落动态发展中自然干扰过程和人类干扰过程的整合以     

青海海北地区高山嵩草草甸植物群落生物量动脉及能量分配

对青海海北地区高山草甸主要植物群落小嵩草草甸,矮嵩草草甸,藏嵩草沼经草甸地下生物量动态和能量分配的研究结果表明,不同植物群落年地上净生产量及其年示动态和主要植物类群生物量季节动态具有明显的差异,其生物量季节动态可由如下模型表示：Ｗｉ＝Ｋｉ（１＋ｅｘｐ（Ａｉ－Ｂｉｔ）植物群落地上,地下生物量的垂直分布呈典型的金字塔和倒金字塔模式。     

古尔班通古特沙漠中4种荒漠草本植物的生物量与化学计量特征

对于荒漠植物不同生长期生物量分配和化学计量比的研究有助于深入了解荒漠植物的功能结构,更好掌握环境对植物的生存影响。本研究选取古尔班通古特沙漠4种一年生荒漠草本植物沙蓬（Agriophyllum sqarrosum（L.）Moq.）、雾冰藜（Bassssia dasyphylla（Fisch.et Mey.）O.Kuntze）、角果藜（Ceratocarpus arenarius L.）和碱蓬（Suaeda glauca（Bge.）Bge.）对比研究了4种生物量分配与N、P化学计量学随植物生长的变化。结果显示：（1）4种荒漠植物生物量积累配过程中,根冠比随生长季的延长逐渐降低。地上、地上生物量相关生长关系表明,角果藜为等速→异速的变化过程,沙蓬从采样初期至末期的变化过程为异速→等速生长,而沙蓬和碱蓬的相关生长指数相反,分别为异速→等速→异速、等速→异速→等速的变化格局;（2）4种植物N、P含量随生长期的延长逐步降低。在整个生长季节4种植物的N与P含量的变化趋势均为相似。（3）植物N、P含量间达到正相关显著,除沙蓬和雾冰藜的N：P之外其余指标分别与植物的地上、地下生物量及总生物量间呈负相关显著,而根冠比、相关生长指数与化学计量特征间未达到显著水平,表明了二者较弱的相关性。研究表明,4种荒漠草本植物生物量与化学计量特征的相关性不大,说明化学计量比并不是影响植物生物量及生活策略的主要因素,而更多是受植物自身遗传特性的影响。同时也体现了荒漠草本植物在养分匮乏的条件下,形成了自身独特的生理生态特征,且具有相对稳定的适应特性。     

青海海北地区高山嵩草草甸植物群落生物量动态及能量分配

对青海海北地区高山草甸主要植物群落小嵩草（Ｋｏｂｒｅｓｉａｐｙｇｍａｅａ）草甸、矮嵩草（Ｋ．ｈｕｍｉｌｉｓ）草甸、藏嵩草（Ｋ．ｔｉｂｅｔｉｃａ）沼泽化草甸地上生物量动态和能量分配的研究结果表明,不同植物群落年地上净生产量及其年际动态和主要植物类群生物量季节动态具明显的差异,其生物量季节动态可由如下模型表示：Ｗｉ＝Ｋｉ／（１＋ｅｘｐ（Ａｉ－Ｂｉｔ））植物群落地上、地下生物量的垂直分布呈典型的金字塔和倒金字塔模式。小嵩草草甸、矮嵩草草甸和藏嵩草沼泽化草甸的地上净生产量依次为３６８．４ｇｍ－２ａ－１、４１８．５ｇｍ－２ａ－１和５１８．４ｇｍ－２ａ－１,所固定的太阳能值依次为６６５５．１６ｋＪｍ－２ａ－１、７６１０．０９ｋＪｍ－２ａ－１、９４８８．７７ｋＪｍ－２ａ－１。光能利用率分别为０．１０９７％、０．１２５６％、０．１５６８％。     

紫苏光合生产与干物质积累的动态模拟

在综合以前研究成果的基础上,兼顾模型的机理性与实用性的平衡,构建了紫苏光合生产与干物质累积的模拟模型.模型采用高斯积分法有效地计算了冠层每日的总光合量,且充分考虑了环境因子中温度和CO_2对光合作用的影响.利用试验资料对模型核实的结果显示,模型可以较好地预测不同生长条件下的生物量累积动态,具有较强的机理性和实用性.     

广义Schumacher模型的改进及其应用

通过对前人提出的生长方程的具体分析,提出了一种改进的Schumacher生长方程．该模型包含了Gompenz函数、Schumacher方程及广义Schumacher方程,具有很强的自适应性和实用性．采用遗传算法。利用该模型对珍稀植物长苞铁杉和侧柏生长资料分别进行了拟合．结果表明,改进的Schumacher方程的拟合精度明显优于Schumache,方程和广义Schumacher方程,也优于经典的Logistic模型和李新运等自适应模型。可以在林木生长动态模拟及种群增长动态研究中广泛应用．     

Simulation Study on the Alkalized-salinized Grassland Ecosystem in the Songnen Plain

Using Object-oriented design and a new programming language JAVA, a physically-based model was built to simulate the hydrological, alkalization/de-alkalization and salinization/desalinization processes in soil. Furthermore, a process-based model was built to evaluate the dynamics of four herbaceous ecosystems (including dynamics of above-ground biomass, below-ground biomass, and litter biomass), each dominated by Aneurolepidium chinense (Trin.) Kitag., Chloris virgata Sw., Puccinellia tenuiflora (Turcz.) Scribn. et Merr. and Suaeda glauca Bunge. This model is a daily-time step model, suitable for simulating hydrological, alkalization/de-alkalization and salinization/desalinization processes of heterogeneous soil, and growth dynamics of different grassland communities. With climatic data and experimental data of Changling Experimental Site in Jilin Province, the soil moisture content (in 1991, 1996, 1997 and 1998), soil salt concentration, exchangeable cation percentage and pH in soil and growth dynamics of these four sorts of grassland communities (in 1991) were simulated and the results were verified to be in accord with observed data.     

Impacts of grazing on the alkalinized–salinized meadow steppe ecosystem in the Songnen Plain,China – A simulation study

A process-based model was built to describe the ecological processes of an alkalinized–salinized meadow steppe ecosystem, including the hydrological and alkalization–salinization processes in the soil, as well as the succession and growth dynamics of the grassland communities. A numerical integration model and a water and salt balance model were integrated into a physically-based model, describing the dynamics of soil moisture, salt concentration, exchangeable sodium percentage (ESP) and pH. Meteorological variables and soil characteristics were the main environmental factors used to estimate the growth dynamics of three herbaceous communities that were dominated by Aneurolepidium chinense, Chloris virgata, and Suaeda glauca, respectively. Model validation showed good agreement between the simulated results and the observed data. Simulation studies were conducted to evaluate the potential changes in hydrological and alkalization–salinization processes, succession and growth dynamics from 1991 to 1998, under five grazing intensities, namely 0%, 25%, 50%, 75% and 90% above-ground biomass removal (AGBR). The simulations show that soil moisture decreased markedly under the 50%, 75% and 90% AGBR, but increased slightly under the 25% AGBR. The de-alkalization and de-salinization processes would be predominant under the 0% AGBR, and the processes became a little slower under the 25% AGBR. In contrast, the 50%, 75% and 90% AGBR accelerated the degradation of soil properties. The grassland was dominated by A. chinense under the 0% AGBR, and by A. chinense and C. virgata under the 25% AGBR. C. virgata could grow on slightly alkalinized–salinized soil and became a dominant species after three years of 50% AGBR. The soil degraded quickly and only S. glauca could grow on the severe alkalinized–salinized soil if the grassland received 75% or 90% AGBR. The grassland grew well under the 0% AGBR, and the biomass stayed at moderate level under 25% AGBR. The 50%, 75% and 90% AGBR decreased the grassland growth greatly. After accumulating the grazed biomass for each year, the 25% AGBR would provide the highest production, and the grassland production would decrease sharply with the increasing of grazing intensities. The simulation results indicate that 25% AGBR is significant for preserving the soil from degradation, and maintaining high grassland production.     

Effects of ground water and harvest intensity on alkaline grassland ecosystem dynamics – a simulation study

A model for the alkaline grassland ecosystems, MAGE, was applied to plant communities dominated by three species. Field observations on two communities dominated respectively by Puccinellia tenuiflora and Suaeda corniculata were used to parameterize the model for multiple species interaction. The model behaves reasonably in following the seasonal variations of water content, soluble sodium cation and calcium cation in surface soil, as well as biomass of the plant communities.Simulations were run to investigate the effects of ground water quality, ground water table depth, maximum non-capillary porosity in surface soil and harvest intensity, on ecosystem dynamics. The results indicated that ground water sodium concentration and ground water table depth had primary control on soil alkalization and vegetation status. The improvement of soil conditions by vegetation is limited to an extent with moderate ground water depth and sodium concentration. Non-capillary pores are critical for vegetation to affect the soil alkalization/de-alkalization process, but the effect of non-capillary pores tends to saturate when maximum non-capillary porosity is greater than 0.1.     

Ecological dynamic model of grassland and its practical verification

Based on the physico-biophysical considerations, mathematical analysis and some approximate formulations generally adopted in meteorology and ecology, an ecological dynamic model of grassland is developed. The model consists of three interactive variables, I.e. The biomass of living grass, the biomass of wilted grass, and the soil wetness. The major biophysical processes are represented in parameterization formulas, and the model parameters can be determined inversely by using the observational climatological and ecological data. Some major parameters are adjusted by this method to fit the data (although incomplete) in the Inner Mongolia grassland, and other secondary parameters are estimated through sensitivity studies. The model results are well agreed with reality, e.g., (I) the maintenance of grassland requires a minimum amount of annual precipitation (approximately 300 mm); (ii) there is a significant relationship between the annual precipitation and the biomass of living grass; and (iii) the overgrazing will eventually result in desertification. A specific emphasis is put on the shading effect of the wilted grass accumulated on the soil surface. It effectively reduces the soil surface temperature and the evaporation, hence benefits the maintenance of grassland and the reduction of water loss in the soil.     

黄土高原典型小流域综合治理的水文生态效应

从流域产流规律及水土保持措施改变引起的土壤水分状况和流域蒸散发的变化等方面评价了黄土丘陵沟壑区泉家沟流域水土保持措施变化对流域水分生态环境的影响.结果表明:水土保持与生态建设过程改变了土地利用结构,对小流域水环境变迁具有很大的影响作用,主要表现在:减少地表径流量,径流模数1996～2000年平均较1980～1985年减少了36.1%;不同治理措施土壤水分状况不同,灌木林地、人工草地和乔木林地均存在深度和厚度不等的土壤"干层";不同地貌部位土壤储水差异很大,阴坡的水分环境优于阳坡,沟底优于峁顶,缓坡优于陡坡;林草措施对流域总蒸散量起着决定性作用,1991～1995年流域林草地面积达到最大,总蒸散量也达到最大,与治理初期相比,总蒸散量累计增加了56.3 mm.     

松嫩盐碱草地植物种群的土壤营养位季节动态

针对松嫩盐碱草地的特点,综合评价了18项土壤因子,以植物的相对地上生物量为土壤营养位效能,分析了松嫩盐碱草地植物种群的土壤营养位季节动态。伴随季节的更替,碱蓬等强耐盐碱植物的土壤营养位中心点逐渐向土壤盐碱程度严重的一侧移动,土壤营养位体积也逐月增加,土壤营养位宽度的扩大是土壤营养位体积增加的主要原因。虎尾草(Chloris virgata)和羊草(Aneurolepidium chinense)的土壤营养位中心点数值和土壤营养位体积7月份时最大。7月份时虎尾草的土壤营养位效能峰值明显高于其它月份的,使得虎尾草此月份的土壤营养位体积在整个生长季内最大,而羊草7月份的土壤营养位宽度和土壤营养位效能峰值都较大,共同决定了该月份羊草的土壤营养位体积最大。除上述植物外,其他轻度耐盐碱植物的土壤营养位中心点随季节更替的变化趋势与碱蓬等强耐盐碱植物的刚好相反,是向土壤盐碱程度越轻的方向。其他轻度耐盐碱植物的土壤营养位宽度8月份时最小,但因为此时土壤营养位效能峰值明显高于其它月份的,它们8月份的土壤营养位体积仍是整个生长季内最大的。松嫩盐碱草地植物种群土壤营养位重叠也存在着明显的季节变化。     

A meta‐analysis of soil salinization effects on nitrogen pools,cycles and fluxes in coastal ecosystems

Salinity intrusion caused by land subsidence resulting from increasing groundwater abstraction, decreasing river sediment loads and increasing sea level because of climate change has caused widespread soil salinization in coastal ecosystems. Soil salinization may greatly alter nitrogen (N) cycling in coastal ecosystems. However, a comprehensive understanding of the effects of soil salinization on ecosystem N pools, cycling processes and fluxes is not available for coastal ecosystems. Therefore, we compiled data from 551 observations from 21 peer‐reviewed papers and conducted a meta‐analysis of experimental soil salinization effects on 19 variables related to N pools, cycling processes and fluxes in coastal ecosystems. Our results showed that the effects of soil salinization varied across different ecosystem types and salinity levels. Soil salinization increased plant N content (18%), soil NH₄⁺ (12%) and soil total N (210%), although it decreased soil NO₃^? (2%) and soil microbial biomass N (74%). Increasing soil salinity stimulated soil N₂O fluxes as well as hydrological NH₄⁺ and NO₂^? fluxes more than threefold, although it decreased the hydrological dissolved organic nitrogen (DON) flux (59%). Soil salinization also increased the net N mineralization by 70%, although salinization effects were not observed on the net nitrification, denitrification and dissimilatory nitrate reduction to ammonium in this meta‐analysis. Overall, this meta‐analysis improves our understanding of the responses of ecosystem N cycling to soil salinization, identifies knowledge gaps and highlights the urgent need for studies on the effects of soil salinization on coastal agro‐ecosystem and microbial N immobilization. Additional increases in knowledge are critical for designing sustainable adaptation measures to the predicted intrusion of salinity intrusion so that the productivity of coastal agro‐ecosystems can be maintained or improved and the N losses and pollution of the natural environment can be minimized.     

香港草地、芒萁、灌木群落的C素动态

通过对香港草地、芒萁、灌木群落植物生物量和净生产量的研究,探讨这些植物群落的C素动态。结果表明草地、芒萁、灌木群落植物的C贮量分别为377,871和1448g/m     

Ecological dynamic model of grassland and its practical verification

Based on the physico-biophysical considerations, mathematical analysis and some approximate formulations generally adopted in meteorology and ecology, an ecological dynamic model of grassland is developed. The model consists of three interactive variables, i.e. the bio-mass of living grass, the biomass of wilted grass, and the soil wetness. The major biophysical processes are represented in parameterization formulas, and the model parameters can be determined inversely by using the observational climatological and ecological data. Some major parameters are adjusted by this method to fit the data (although incomplete) in the Inner Mongolia grassland, and other secondary parameters are estimated through sensitivity studies. The model results are well agreed with reality, e.g., (i) the maintenance of grassland requires a minimum amount of annual precipitation (approximately 300 mm); (ii) there is a significant relationship between the annual precipitation and the biomass of living grass; and (iii) the overgrazing will eventually result in desertification. A specific emphasis is put on the shading effect of the wilted grass accumulated on the soil surface. It effectively reduces the soil surface temperature and the evaporation, hence benefits the maintenance of grassland and the reduction of water loss in the soil.     

土壤盐碱化程度及非毛管孔隙度对羊草群落生物量及优势度的影响

通过对不同盐碱化土壤上的羊草群落进行及定位连续观测,分析了它和土壤盐碱化程度及非毛管孔隙度之间的相互关系,探讨了盐碱生境下羊草群落生物量的形成规律以及土 盐碱化程度对其影响,结果证明,盐碱生境对羊草群落在一个生长季内的生物量形成过程无本质影响;群落的生物量随返青后天数增加而呈S型曲线上升,二者间的数学关系可用修改的Logistic方程Y＝Y m/1 Ae-bx C描述。土壤盐碱化程度可影响该方程的各参数,随土 盐碱化程度加剧,生物量最大增长值Ym和本底生物量C明显变小,到达S型曲线拐点的天数减少,羊草群落生态优势度随土壤盐度增大呈倒S型曲线下降,随土壤非毛管孔隙度增大而呈正S型曲线上升,三者之间的回归分析结果表明,土壤盐度和非毛管孔隙度都是影响优势度的不同忽略的重要因素,但前者的重要性大于后者。用方程可获得最佳拟合结果及3个生态因子相互关系的总体模型。