幼龄柠条细根现存量与环境因子的关系

以晋西北黄土高原区柠条(Caragana korshinskii)幼龄人工林为研究对象, 应用微根管技术(Minirhizotron technique)对林地100 cm土层范围的柠条细根生长动态进行了观测。以2007年生长季(5~9月)的根长密度(RLD, mm·cm^-3)数据为基础, 对柠条细根现存量(RLDst, mm·cm^-3)及其与环境因子(≥10 ℃积温、同期土壤积温、积降雨量和土壤水分等)的关系作了研究。结果表明, 40~90 cm土层是柠条细根的主要分布区和生长活跃区, 其细根占细根总量的59.7%。柠条细根现存量的季节变化特征为: 5月至9月上旬RLDst持续增加, 9月下旬RLDst略有降低。柠条细根现存量季节变化与≥10 ℃积温、同期土壤积温和积降雨量均存在极显著正相关关系。     

短期增温和增加降水对内蒙古荒漠草原土壤呼吸的影响

利用红外辐射增温装置模拟短期持续增温和降水增加交互作用对内蒙古荒漠草原土壤呼吸作用的影响, 结果表明: 土壤含水量对月土壤呼吸的影响显著大于土壤温度增加的影响, 生长旺季的月土壤呼吸显著大于生长末季; 土壤温度和水分增加都显著影响日土壤呼吸, 但二者的交互作用对土壤呼吸无显著影响。荒漠草原7‒8月平均土壤呼吸速率为1.35 μmol CO₂·m ^-2·s ^-1, 7月份为2.08 μmol CO₂·m ^-2·s ^-1, 8月份为0.63 μmol CO₂·m ^-2·s ^-1。土壤呼吸与地下各层根系生物量呈幂函数关系, 0‒10 cm土层的根系生物量对土壤呼吸的解释率(79.2%)明显高于10‒20 cm土层的解释率(31.6%)。0-10 cm土层的根系生物量是根系生物量的主体, 根系生物量对土壤呼吸的影响具有层次性。在未来全球变暖和降水格局变化的情景下, 荒漠草原土壤水分含量是影响生物量的主导环境因子, 而根系生物量的差异是造成土壤呼吸异质性的主要生物因素, 土壤含水量可通过影响根系生物量控制土壤呼吸的异质性。     

毛竹种群向常绿阔叶林扩张的细根策略

为了探讨毛竹(Phyllostachys pubescens)种群向常绿阔叶林扩张的根系策略, 该文采用根钻法和内生长法, 在江西大岗山选取毛竹林与阔叶林的交错区——竹阔界面(bamboo-broad-leaved forest interface), 并垂直于界面连续设置毛竹林、毛竹与阔叶树的混交林(以下简称为竹阔混交林)、常绿阔叶林3种样地, 比较分析其细根的空间分布格局、比根长、根长密度、生长速率和周转率等指标。结果表明: 毛竹林细根生物量(1201.60 g·m^-2) >竹阔混交林(601.18 g·m ^-2) >常绿阔叶林(204.88 g·m ^-2); 在毛竹与阔叶树竞争的混交林中, 毛竹细根分布趋向于上层土壤(与毛竹林细根相比), 且其比根长也显著增加, 平均增幅高达123.42%, 总根长密度比阔叶树大2.1倍; 同时, 毛竹细根生长速率和周转率均高于阔叶树。这些结果说明毛竹可通过广布、精准、灵活、快速等细根竞争策略, 提高资源获取能力, 实现种群扩张。     

沙蒿(Artemisia ordosica)水浸提液对4种伴生草本植物的化感作用

以生长在我国荒漠和半荒漠地区的特有植物沙蒿为供体植物,沙米、虫实、草木樨状黄芪、狗尾草为受体植物,研究了沙蒿根、茎、叶、种子水浸提液对受体植物种子发芽、幼苗生长以及根对NH~+_4和K~+吸收的化感效应的差异,为沙区植被恢复中伴生杂草种类的选择提供理论依据。结果表明:沙蒿水浸提液对4种受体植物种子发芽和幼苗生长均具有显著的化感效应,沙米、虫实、草木樨状黄芪表现为抑制作用,狗尾草表现为促进作用。不同部位沙蒿浸提液的化感作用不同,根浸提液对沙米、虫实、狗尾草的化感效应最强,茎浸提液对草木樨状黄芪的抑制最强。不同植物种及植物的不同发育时期对化感作用的敏感性也不同,在4种受体植物中,沙米受抑制最强,其次为虫实、草木樨状黄芪,且随浸提液浓度增加而显著增强,而狗尾草具有一定的耐受力,表现为促进作用。沙蒿浸提液对受体植物根长的影响最强,其次是种子发芽、苗高和幼苗干质量。浸提液显著降低沙米、虫实、草木樨状黄芪根对NH~+_4和K~+的吸收,增加狗尾草根对NH~+_4和K~+的吸收。研究结果表明雨水淋溶是沙蒿向环境中释放化感物质的途径之一,化感作用在增强沙蒿生存竞争力,扩大种群过程中起着不容忽视的作用,可能是沙蒿单优势种群落形成的原因之一。     

黑河中游荒漠草地地上和地下生物量的分配格局

草地生态系统中地上和地下生物量的分配方式对于研究生态系统碳储量和碳循环有着重要的意义。为了解黑河中游荒漠草地的地上和地下生物量分配格局, 从群落和个体两个水平对黑河中游的地上和地下生物量进行了调查。结果表明: 群落水平上地上生物量介于3.2-559.2 g·m^-2之间, 地下生物量介于3.3-188.2 g·m^-2之间, 个体水平上地上生物量介于6.1-489.0 g·株^-1之间, 地下生物量介于2.4-244.2 g·株^-1之间, 群落水平上的根冠比(R/S)为0.10-2.49, 个体水平上为0.07-1.55, 地下生物量均小于地上生物量, 群落水平上R/S值大于个体水平。群落和个体水平地上和地下生物量的拟合斜率分别为1.1001和0.9913, 与1没有显著差异, 说明地上与地下生物量呈等速生长关系。群落和个体水平土壤表层0-20 cm和0-30 cm的根系生物量分别占全部根系生物量的89.81%、96.95%和81.42%、93.62%, 表明地下生物量主要集中在0-20 cm和0-30 cm土壤表层。     

种子散布位置对格氏栲幼苗根系形态及生长特征的影响

种子从母株掉落于地面萌发后,其根系在不同散布位置(凋落物上层、土壤表层和凋落物下层)的生长形态影响幼苗定居及建成,而目前对其根系形态及生长特征的了解并不充分,限制了对幼苗根系在不同散布下适应策略的理解。为此,以格氏栲(Castanopsis kawakamii)为研究对象,通过模拟种子在凋落物中位置,设置凋落物上层(种子下层铺垫2 cm和4 cm凋落物,U2和U4处理)、土壤表层与凋落物下层(种子上层覆盖0、2、4、6 cm和8 cm凋落物,CK、D2、D4、D6和D8处理)等3种散布,探讨不同散布位置对格氏栲幼苗根系9个生长指标的影响。结果表明：(1)种子散布位置对幼苗根干物质质量具有显著影响,D2处理达最大值。(2)D2处理的幼苗根长、根表面积、根尖数、分枝数和比根长高于其它处理;根系平均直径在D6处理达最大值。(3)相关分析表明根长、根表面积、根尖数、分枝数和比根长与根系平均直径呈显著负相关关系。(4)对根系9个生长指标提取主成分后聚类为4个类群,D2与D4处理各划分一类;U2与U4处理划分一类,其余三个处理划分一类。综上所述,凋落物浅层覆盖(D2处理)适宜格氏栲根系生长;凋落物...     

黄土丘陵区撂荒群落演替序列种根系对氮素施肥方式和水平的形态响应

采用盆栽试验,研究了黄土丘陵区撂荒群落演替序列种(即,黄土丘陵区摞荒群落演替主要阶段的优势种)根系对氮素施肥方式和水平的形态响应,对了解我国氮沉降增加背景下的群落生态效应及人为施肥干扰促进植被恢复具有较好的理论和实践意义。测试并分析了6个演替序列种在不同施氮方式(匀质和异质施氮)和水平(高、低和无氮对照)条件下植株个体生物量指标(地上及地下生物量和根冠比)、根系形态指标(根长、直径、表面积、比根长和比表面积)的变化及其差异显著性;并且利用根钻法和单样本T检验比较了异质施氮方式下施氮斑块与不施氮斑块根系形态指标的差异。结果表明:1)6种演替序列种地上、地下生物量和根冠比存在种间固有差别,施氮方式和水平整体上对三者无显著影响;施氮方式和植物种类对根冠比存在显著交互作用,说明个别种的根冠比对施氮方式响应明显,其中猪毛蒿根冠比在异质施氮方式下显著高于匀质施氮。2)6种演替序列种根系塑形指标包括比根长、比表面积和直径存在种间差别,并且施氮水平对比根长影响显著,高、低施氮水平下比根长都显著低于不施氮对照。3)狗尾草和铁杆蒿分别在异质高氮和异质低氮条件下施氮斑块根系生物量密度显著高于未施氮斑块;猪毛蒿在异质高氮条件下施氮斑块发生了更多的伸长生长,其根长、根表面积、比根长和比表面积在施氮斑块中的密度显著高于未施氮斑块;猪毛蒿和狗尾草在异质高氮条件下,以及白羊草在异质低氮条件下,其根系直径在施氮斑块显著小于未施氮斑块。从根系形态变化敏感性和施氮对促进植物生长来看,演替过程中演替序列种对施氮响应的敏感性总体上呈降低趋势,前期种对施氮响应更敏感,从施氮获利也更多,因而恢复前期进行人为干扰促进植被恢复效果也会更好。     

多枝柽柳幼苗根系形态及生物量对不同灌溉处理的响应

多枝柽柳(Tamarix ramosissima)是塔里木河下游荒漠河岸林中的优势灌木, 对荒漠河岸植被群落的稳定起着重要作用。该文通过研究多枝柽柳幼苗根系形态对不同灌溉处理的响应, 分析人工水分干扰对多枝柽柳幼苗根系生长的影响。实验设计了侧渗分层和地表灌溉两种给水方式和高灌(50 L∙株 ^-1)、中灌(25 L∙株 ^-1)、低灌(12.5 L∙株 ^-1)三个给水水平, 并在整个生长季节监测每个植株的生物量及根系形态参数。结果显示: 与地表灌溉比较, 侧渗分层的灌溉方式显著提高了细根(0.5 mm < d < 2 mm)长、细根表面积和根系生物量, 并使根系生长至160 cm深度的土层, 大于地表灌溉深度(80-100 cm); 侧渗分层灌溉+高灌的组合促进根系生长的效果最显著(p < 0.05); 侧渗分层灌溉方式下总细根(d < 2 mm)的比根长随着给水量的增加显著增大, 而地表灌溉下比根长无显著变化; 侧渗分层灌溉方式下根冠比总体小于地表灌溉方式, 即侧渗分层灌溉使多枝柽柳地上部分发育较好。因此, 侧渗分层灌溉方式有显著促进多枝柽柳幼苗在生长早期快速发育的效果。     

琼东海域橙黄滨珊瑚骨骼生长特性及其主要影响因素

基于珊瑚骨骼X射线照片,使用CoralXDS软件,对海南岛(琼)东部海域的橙黄滨珊瑚生长特性进行研究,获取了百年来的年生长率(ER)、骨骼密度(D)和钙化速率(CR) 3种生长参数.结果表明: 该橙黄滨珊瑚ER的变化范围为0.49～1.10 cm·a^-1,年均值0.76 cm·a^-1;D的变化范围1.11～1.35 g·cm^-3,年均值1.22 g·cm^-3;CR的变化范围为0.55～1.41 g·cm^-2·a^-1,年均值0.94 g·cm^-2·a^-1.统计分析表明,研究海区表层水温(SST)是橙黄滨珊瑚骨骼生长参数变化的主要环境影响因素,对ER和CR的控制较强,对D的影响较弱,但总体上3项生长参数都随SST升高而增大.光照、盐度和水动力条件等是次要影响因素.台风和强热带风暴对琼东海域橙黄滨珊瑚骨骼密度条带分布的影响也较为显著.复杂的气候环境,赋予了橙黄滨珊瑚骨骼多变的生长模式.过去一个世纪以来,琼东海域年平均表层水温显著上升,气候倾向率为0.15 ℃·(10 a)^-1,SST上升分为两个阶段,20世纪40年代初和80年代初,人类活动加剧和全球气候变暖是导致琼东海域SST显著上升的原因.     

小麦和玉米根系取样位置优化确定及根系分布模拟

为了确定小麦(Triticum aestivum)、玉米(Zea mays)根系的最优取样位置和更准确地模拟根长密度在土壤剖面的分布, 在冬小麦和夏玉米的灌浆后期, 采用根钻法取样, 比较了不同取样位置对根系分布的影响; 采用Gerwitz和Page模型对根长密度的分布进行了模拟。结果表明, 冬小麦行间和行上取样在0-10 cm土层根长密度差异显著, 在10 cm以下土层差异减少。在确定根长密度分布的取样中, 在0-20 cm土层应考虑根长密度分布的空间差异, 即行上密度大于行间密度; 而在20-100 cm土层, 需要考虑行间根长密度大于行上的空间差异; 在1 m以下土层两个位置的差异逐渐消失, 可不考虑空间差异。夏玉米根长密度在上层土壤表现出距离植株不同位置差异显著的特征。植株位置(株上)、距植株10 cm和距植株20 cm位置根长密度在土壤中的分布特征是: 0-10 cm土层3个位置根长密度差异在50%以上, 根长密度大小是株上>距植株10 cm>距植株20 cm; 而在10-30 cm层次, 根长密度表现为距植株10 cm>株上>距植株20 cm, 30-50 cm土层株上位置的根长密度最小, 50 cm以下各位置根长密度差异不明显。对于玉米根系取样, 50 cm以上土层需要考虑根长密度的空间差异, 50 cm以下土层可不考虑。采用Gerwitz和Page模型, 结合华北平原机械化耕作下形成的土壤犁底层变厚及其犁底层容重增加对根系分布的影响, 在模型中加入土壤容重参数订正可以使模型更准确地模拟根长密度在土壤剖面的分布。     

沙埋对两种沙生植物幼苗生长的影响及其生理响应差异

为了解沙埋对沙生植物生长的影响及其生理响应特征, 比较不同沙生植物耐沙埋能力及其机制, 2010年在内蒙古科尔沁沙地研究了不同深度沙埋下沙蓬(Agriophyllum squarrosum)和盐蒿(Artemisia halodendron)幼苗的存活率、株高等生长特性及其渗透调节物质含量, 保护酶活性和膜透性的变化, 得到以下结果: 沙蓬和盐蒿幼苗均具有较强的耐沙埋能力, 其中沙蓬幼苗最大耐沙埋深度超过幼苗10 cm, 盐蒿幼苗最大耐沙埋深度超过其株高8 cm; 随着沙埋深度增加, 沙蓬和盐蒿幼苗的存活率和株高均显著下降, 沙蓬的下降幅度显著小于盐蒿; 沙埋处理下两种植物均未表现出受水分胁迫, 沙埋导致其光合面积下降, 幼苗顶土困难, 是影响其存活和高生长的主要生态机制; 随着沙埋深度增加, 沙蓬幼苗丙二醛(MDA)含量显著增加, 盐蒿幼苗MDA含量下降, 虽然二者膜透性均呈增加趋势, 但沙蓬膜透性增加幅度显著低于盐蒿, 说明细胞膜受损是导致二者幼苗存活率下降和生长受到抑制的主要生理机制, 沙蓬膜透性受损程度较低是其耐沙埋能力较强的主要生理机制; 沙埋胁迫下, 虽然两种植物都通过提高过氧化物酶活性和脯氨酸含量减轻细胞膜受损程度, 但沙蓬体内超氧化物歧化酶也表现出重要协调作用, 使之酶促系统在保护细胞膜免受胁迫损伤过程中的作用更有效。     

Effects of burial in sand and water supply regime on seedling emergence of six species

BACKGROUND AND AIMS: Air seeding has long been regarded as a quick and successful measure for vegetation rehabilitation in China. However, seedling emergence of often-used species including Agriophyllum squarrosum, Artemisia sphaerocephala, Artemisia ordosica, Hedysarum fruticosum, Caragana korshinskii and Medicago sativa is low. Experiments were conducted under controlled conditions to study the effects of sowing depth and water supply on seedling emergence, in order to understand the requirements for increasing seedling emergence. METHODS: Seeds were exposed to different environments of burial and water supply regimes in PVC pots (7 cm in diameter and 11 cm in height) under the same light intensity and alternating temperature regimes in a growth chamber. KEY RESULTS: Seedlings of three species (Agriophyllum squarrosum, Artemisia sphaerocephala, Artemisia ordosica) with relatively light seeds emerged well at a 0.5 cm sowing depth under a 7.5 and 10 mm water supply regime. However, few seedlings of these species emerged when the sowing depth was over 1 cm or when water supply was 5 mm. Seedlings of Caragana korshinskii, Hedysarum fruticosum and Medicago sativa emerged from sowing depths of 0.5-4 cm, 0.5-3 cm, and 0.5-4 cm, respectively, under both 7.5 and 10 mm water supply regimes. Under a 5 mm water supply regime, seedlings of these species also emerged at over 1 cm sowing depth. Seeds of all six species sown on the surface of sand did not germinate, and seedlings did not emerge when they were sown at depths greater than 6 cm. CONCLUSIONS: Based on these experiments, a 0.5 cm sowing depth resulted in the highest seedling emergence and it is concluded that this is the optimal sowing depth for seedling emergence of all six species.     

A comparison of soil core sampling and minirhizotrons to quantify root development of field-grown potatoes

Root growth of potato (Solanum tuberosum L.) is sensitive to soil conditions. A reduced root system size can result in reduced uptake of water and/or nutrients, leading to impaired crop growth. To understand the mechanisms by which soil conditions affect crop growth, study of temporal and spatial development of roots is required.In field experiments, effects of soil temperature, soil compaction and potato cyst nematodes (Globodera pallida) on root growth of potato cultivars were studied using two methods: core sampling and vertically oriented minirhizotrons.Minirhizotrons showed relatively more roots in deeper soil layers than core sampling, probably because of preferential root growth along the tube. Spatial distribution of roots should therefore be analysed by core sampling.To eliminate differences in spatial distribution, total root systems as measured by both methods were compared. Nematodes, cultivars and time did not affect the relationship between both methods. Soil compaction, however, affected it because of a strong response of root length in bulk soil and small differences in root number against the minirhizotron, suggesting that soil coring has to be used to study effects of different bulk densities.With both methods, sequential measurements of roots give the net effect of root growth and decay. Data on root turnover can only be obtained with minirhizotrons by comparing video recordings of different dates. Other information obtained with minirhizotrons is the average orientation of roots. Moreover, the minirhizotron method has the advantage of demanding less labour.     

Vertical and horizontal development of the root system of carrots following green manure

Cover crops grown as green manure or for other purposes will affect nitrogen (N) distribution in the soil, and may thereby alter root growth of a succeeding crop. During two years, experiments were performed to study effects of nitrogen supply by green manure on root development of carrots (Daucus carota L). Total root intensity (roots cm⁻² on minirhizotrons) was significantly affected by the green manures, and was highest in the control plots where no green manure had been grown. Spread of the root system into the interrow soil was also affected by green manure treatments, as the spread was reduced where spring topsoil N_min was high. Although N supply and distribution in the soil profile differed strongly among the treatments, no effect was observed on the rooting depth of the carrot crops. Across all treatments the rooting front penetrated at a rate of 0.82 and 0.68 mm day⁻¹ °C⁻¹ beneath the crop rows and in the interrow soil, respectively. The minirhizotrons only allowed measurements down to 1 m, and the roots reached this depth before harvest. Extrapolating the linear relationship between temperature sum and rooting depth until harvest would lead to rooting depths of 1.59 and 1.18 m under the crop rows and in the interrow soil respectively. Soil analysis showed that the carrot crop was able to reduce N_min to very low levels even in the 0.75 to 1.0 m soil layer, which is in accordance with the root measurements. Still, where well supplied, the carrots left up 90 kg N ha⁻¹ in the soil at harvest. This seemed to be related to a limited N uptake capacity of the carrots rather than to insufficient root growth in the top metre of the soil. This revised version was published online in June 2006 with corrections to the Cover Date.     

Temporal and spatial root development of cauliflower (Brassica oleracea L. var. botrytis L.)

Row crops are often inefficient in utilizing soil resources. One reason for this appears to be inefficient rooting of the available soil volume. Five experiments were performed to study the temporal and spatial root development of cauliflower (cv. Plana). The crop was grown with 60 cm between rows, and root development was followed in minirhizotrons placed under the crop rows, 15 cm, and 30 cm from the crop rows. Soil was sampled and analyzed for nitrate content at the final harvest and once during growth. In two of the experiments N fertilizer rate was varied and in two of the other experiments two cultivars were compared (cv. Plana and Siria).The rooting depth of cauliflower was found to be linearly related to temperature sum, with a growth rate of 1.02 mm day^-1 °C^-1. Depending on duration of growth this leads to rooting depths at harvest of 85–115 cm. Soil analysis showed that the cauliflower was able to utilize soil nitrogen down to at least 100 cm.With Plana differences in root growth between row and interrow soil were only observed during early growth, but with Siria this difference was maintained until harvest. However, at harvest both cultivars had depleted row and interrow soil nitrate equally efficient. Nitrogen fertilizer did not affect overall root development significantly.The branching frequency of actively branching roots was increased in all soil layers from about 6 to 10 branches cm^-1 by increasing N fertilizer additions from 130 to 290 kg N ha^-1. Increasing N supply increased the number of actively branching roots in the topsoil and reduced it in the subsoil.The average growth rate of the roots was always highest in the newly rooted soil layers, but fell during time. At 74 days after planting very few roots were growing in the upper 60 cm of the soil whereas 70% of the root tips observed in the 80–100 cm soil layer were actively growing. Within each soil layer there was a large variation in growth rate of individual root tips.     

科尔沁沙地流动沙丘3种常见植物的空间分布格局与异速生长

研究流动沙丘上物种小尺度分布格局和植物异速分配特点有助于理解植物在流动沙丘生境上的适应策略.调查了科尔沁沙地28个1 m×1 m样方内沙蓬、烛台虫实和狗尾草3个物种的位置、多度、高度以及生物量信息.采用最近邻体法与O-ring O(r)函数方法进行空间格局分析.结果表明： 在1 m×1 m样方内,群落水平上植物个体间以聚集分布为主,而在种群水平上物种大体以随机分布为主;个体间距离在0～50 cm范围内无论种内还是种间,它们以互助作用为主,在特定尺度上物种出现聚集分布并随1 m×1 m样方内植物多度增加而变化.在0～40 cm内,沙蓬和狗尾草聚集分布增加;在10～20 cm内,3个物种的种内和种间聚集均增加;在10～30 cm内,狗尾草与沙蓬、烛台虫实出现种间正相关的概率增加;在40～50 cm内,沙蓬与烛台虫实以及沙蓬与狗尾草出现正相关的概率增加.物种构件结果表明：3个物种地上部分生长速度显著大于地下部分,狗尾草根冠比最大且营养器官的生物量比例居中,烛台虫实分配给生殖器官和茎的生物量比重较大,沙蓬分配给营养器官的比重较大.结合小尺度上的格局分析与构件分配特点,可以推断3种植物是典型的r对策者.     

科尔沁沙地69种植物种子重量比较研究

 研究了科尔沁沙地69种植物的繁殖体（30种为种子,39种为果实）重量。结果表明：1）传播体为果实的植物可分为4个组别（即果实单粒重<0.1 mg、0.1～0.999 9 mg、1～9.999 9 mg、10～99.999 9 mg）;黄蒿（Artemisia scoparia）果实(0.051 7 mg)和小香蒲（Typha minima）果实(0.068 2 mg)最轻,苍耳（Xanthium sibiricum）单个果实（77.894 3 mg）最重;2）传播体为种子的植物可分为3个组别（即种子单粒重0.1～0.999 9 mg、1～9.999 9 mg、10～99.999 9 mg）;马齿苋（Portulaca oleracea）种子（0.151 4 mg）最轻,苦参（Sophora flavescens）种子(46.781 6 mg)最重;3）黄蒿、马齿苋、轮叶沙参（Adenophora tetraphylla）、碱地肤（Kochia sieversiana）、狼尾花（Lysimachia barystachys）、灰绿藜（Chenopodium glaucum）、刺沙蓬（Salsola ruthenica）、菟丝子（Cuscuta chinensis）、大籽蒿（Artemisia sieversiana）、狗尾草（Setaria viridis）、野古草（Arundinella hirta）等植物所以广泛分布可能是因为它们繁殖体轻（<1 mg）且具有持久土壤种子库;4）流沙上的先锋植物或沙生演替系列前期植物沙蓬（Agriphyllum squarrosum）、差巴嘎蒿（Artemisia halodendron）、乌丹蒿（Artemisia wudanica）、狗尾草、雾冰藜（Bassia dasyphylla）的繁殖体要么重量居中或偏大,要么有降低位移的其它机制。     

沙米表型可塑性对土壤养分、水分和种群密度变化的响应

研究了土壤营养、土壤水分和种群密度等环境因素对沙米表型可塑性的影响.结果表明：土壤营养、土壤水分和种群密度对沙米的形态特性和生物量具有显著影响;随着土壤营养的增加,沙米的根冠比从0.135减小到0.073,但与土壤水分和种群密度无显著相关关系.对土壤营养和土壤水分变化响应的沙米繁殖分配可塑性是“真正的可塑性”; 沙米繁殖分配与土壤营养呈负相关,与土壤水分呈正相关; 在高土壤营养或低土壤水分条件下,沙米的繁殖分配随个体大小变化的速率较大;种群密度对沙米的繁殖分配无影响,其繁殖分配主要受个体大小的制约.在3个环境因素中,土壤营养对沙米形态特性和生物量特性的可塑性影响最大.     

Spatial variation in tree root distribution and growth associated with minirhizotrons

Four minirhizotrons were installed in each of three replicate plots in a deciduous forest dominated by Acer saccharum Marsh. The length growth of tree roots along the surface of the minirhizotrons was measured for a period of one year, and the resulting data were analyzed in nested, averaged and pooled arrangements. The analyses of nested data showed that spatial variation in root growth and abundance among minirhizotrons within plots was greater than variation among plots. Averaging data from minirhizotrons within plots prior to analysis reduced variation about plot means, but extensive intraplot variation invalidates this approach on statistical grounds. Both nested and averaged data failed to account for the contribution of individual roots to the mean, and root production rates were consequently overestimated. Pooling the data from the four minirhizotrons reduced variation about the means, and resulted in a more representative estimate of root production rates. The analysis of composited data can be used to incorporate small-scale variation into a single replicate sample in those circumstances where the activity of the root systems of plant communities is the object of study.     

不同风沙条件对几种植物生态生理特征的影响

 在野外风洞条件下,就不同风况的风沙胁迫对几种固沙植物生态生理特征的影响进行了实验研究。实验采用了沙坡头地区的野外植物和盆栽植物。在不同风速(5.9 m·s-1, 7.9 m·s-1, 9.9 m·s-1,14 m·s-1, 10 m·s-1,15 m·s-1, 20 m·s-1)和吹袭时间间隔(2 d, 4 d, 9 d)下测定了植物3个生理生态参数的变化。实验结果表明：1）净风和风沙流胁迫均可使植物的净光合速率（Pn）降低,蒸腾速率（E）升高,从而导致水分利用效率（WUE）下降。净风和风沙流对植物生理生态特征的影响显著不同。同样为14 m·s-1的风速时,风沙流使植物的Pn降低40.7%,而净风使其降低了35.88%。2）吹袭的时间间隔越短,植物的净光合速率降幅越大;风沙流比净风的影响更大。在2 d, 4 d, 9 d为间隔的风沙流吹袭下,油蒿（Artemisia ordosica）的Pn分别下降了20.13%、 11.76%、 7.72%。风沙胁迫强度越大,物质积累越少,植物的高生长越慢。3）由于风沙流降低了水分利用率,从而增加了对植物的干燥作用。从总体来看,沙生植物对风沙流胁迫有一定的适应响应,实验所用灌木较草本植物有更强的抗风性。