黄土高原丘陵沟壑区小流域植被净第一性生产力模型

构建了机理性植被净第一性生产力模型(Vegetation—Soil—Integrated—Model,VSIM)。该模型将土壤水分动态过程与植被生长过程相耦合,用以分析黄土高原丘陵沟壑区土壤水分对植被生产力的影响。模型考虑了叶片尺度上气孔导度对净光合过程和蒸腾过程的影响,在此基础上通过考虑植被冠层结构和地形因素的影响对模型进行尺度转换,并以位于黄土高原丘陵沟壑区纸坊沟流域的观测数据对模型进行参数化和验证。结果表明对于生物量的模拟草本和半灌木比乔、灌木好．主要植被类型LAI的季节变化与观测结果具有很好的一致性,模型能够反映出流域降雨一产流过程,并且基本上也能够反映土壤水分的时空变化范围。模拟结果表明,刺槐林和苹果林属于高光合一低蒸腾类型,农作物、白羊草群落和达乌里胡枝子群落属于高光合一高蒸腾类型,铁杆蒿群落和茭蒿群落属于低光合一低蒸腾类型,而沙棘灌丛和柠条灌丛的净第一性生产力居中,但蒸腾量较高。流域内土壤水分在多年序列上基本平衡,而在不同的水文年表现出失衡。其中刺槐林、苹果林和沙棘灌丛的多年平均土壤水分在年内存在少量亏缺,铁杆蒿群落和茭蒿群落略有增加,而其它植被类型基本保持平衡。丰水年不同植被类型土壤含水量都明显高于欠水年,土壤水分含量的变化在丰水年表现为盈余,而在欠水年表现为明显的亏缺。     

半干旱矿区3种灌木侧根分支处折力损伤后的自修复特性

以神东矿区用于植被恢复的小叶锦鸡儿、沙柳、沙棘为对象,研究侧根分支处极限抗折力学特性及受力受损后生长指标、力学特性的自修复能力,以明确半干旱采煤沉陷区灌木侧根分支处在遭受外力损伤后的可持续固土能力.结果表明: 3种灌木生长季初期侧根分支处极限抗折力和抗折强度均存在显著差异,种间变化均表现为小叶锦鸡儿>沙柳>沙棘.小叶锦鸡儿和沙柳侧根分支处抗折强度与纤维素、木质素及棕纤维素含量呈显著正相关,沙棘抗折强度与纤维素和木质素含量呈显著负相关,与棕纤维素含量呈显著正相关.沉陷区形成的折力损伤显著破坏灌木侧根分支处的正常生长和力学特性,即使通过3个月的自修复也不能恢复到未受损水平.生长指标自修复能力越强,抗折力自修复程度越高,修复率种间变化为沙棘(91.2%)>沙柳(82.0%)>小叶锦鸡儿(73.9%),抗折力修复率种间变化为沙棘(41.4%)>沙柳(37.1%)>小叶锦鸡儿(30.0%).3种灌木侧根分支处可持续固土指数分别为小叶锦鸡儿(2.2084)>沙柳(0.2009)>沙棘(-2.4093),说明在半干旱采煤沉陷区小叶锦鸡儿可持续固土能力最强,沙柳次之,沙棘最弱.     

水分胁迫对沙棘(Hippophae rhamnoides)和中间锦鸡儿(Caragana intermedia)蒸腾作用影响的比较

多年生灌木沙棘和中间锦鸡儿是黄土高原生态重建的重要物种,设计人工模拟水分胁迫实验,测量沙棘和中间锦鸡儿蒸腾作用的各种指标,研究其蒸腾特性对水分胁迫的适应方式。结果表明,同等水分处理条件下,中间锦鸡儿单叶水平上的蒸腾速率高于沙棘。沙棘和中间锦鸡儿的蒸腾速率日进程在晴天、阴雨天和生长发育的不同阶段明显不同。夜间蒸腾占全天蒸腾的比例相当大,夜间蒸腾在不同物种之间、不同供水量之间存在明显差异,而且越干旱的环境比例越大。两种植物气孔阻力的季节变化格局在不同水分处理间大体相似。沙棘的昼夜蒸腾节律在各种水分处理条件下都表现出明显的气孔振荡现象,而中间锦鸡儿没有。叶片温度、光合有效辐射和气孔阻力是各种水分条件下沙棘和中间锦鸡儿蒸腾作用的共同的限制因子,相对于沙棘,中间锦鸡儿还更多地受到空气相对湿度的影响。     

水分胁迫对沙棘(Hippophae rhamnoides)和中间锦鸡儿(Caragana intermedia)蒸腾作用影响的比较

多年生灌木沙棘和中间锦鸡儿是黄土高原生态重建的重要物种,设计人工模拟水分胁迫实验,测量沙棘和中间锦鸡儿蒸腾作用的各种指标,研究其蒸腾特性对水分胁迫的适应方式。结果表明,同等水分处理条件下,中间锦鸡儿单叶水平上的蒸腾速率高于沙棘。沙棘和中间锦鸡儿的蒸腾速率日进程在晴天、阴雨天和生长发育的不同阶段明显不同。夜间蒸腾占全天蒸腾的比例相当大,夜间蒸腾在不同物种之间、不同供水量之间存在明显差异,而且越干旱的环境比例越大。两种植物气孔阻力的季节变化格局在不同水分处理间大体相似。沙棘的昼夜蒸腾节律在各种水分处理条件下都表现出明显的气孔振荡现象,而中间锦鸡儿没有。叶片温度、光合有效辐射和气孔阻力是各种水分条件下沙棘和中间锦鸡儿蒸腾作用的共同的限制因子,相对于沙棘,中间锦鸡儿还更多地受到空气相对湿度的影响。     

黄河中游砒砂岩地区土地利用对生物多样性的影响评价

作者以长川流域附近的阿贵庙自然保护区的主要植被类型为对照,通过对黄河中游砒砂岩地区长川流域内的各土地利用/覆盖类型之间的生物多样性的比较分析,综合评价了人类土地利用活动对当地生物多样性的影响。结果表明:沙棘(Hippophaerhamnoides)灌丛、草地、油松(Pinustabuliformis)林地和中间锦鸡儿(Caraganainter-media)灌丛等土地利用类型的生物多样性指数较高;进一步运用S?renson指数分析发现,仅中间锦鸡儿灌丛、草地和油松林三类与主要自然植被类型有着较高的相似性,其S?renson指数均在40%左右。综合考虑Shannon-Wiener指数与S?renson指数,草地、中间锦鸡儿灌丛、油松林地等类型对当地物种多样性的影响相对较弱,有利于当地物种多样性的保护,在植被恢复和建设过程中应相对增大种植比例。     

黄土高原常用造林树种水分利用特征

在适宜土壤水分、中度干旱和严重干旱3种土壤水分条件下研究了黄土高原干旱、半干旱地区常用的人工造林树种84k杨树（Populus spp．）、刺槐（Robinia pseudoacacia）、沙棘（Hippophae rhamnoides）和油松（Pinus tabulaeformis）苗木生长及水分利用特征。结果显示,干旱胁迫使各树种成活率、生长速率、光合速率均显著下降;84k杨树和刺槐单叶水分利用率（WUE）在适宜水分下最高,沙棘的在中度干旱下最高;在中度干旱下,4个树种的总水分利用率最高。而严重干旱下最低。无论干旱与否,4个树种中沙棘生长速率最高。在中度干旱条件下,4个树种均可良好生长,而严重干旱下生长均受到显著抑制,其中84k杨树受影响最大;4个树种中沙棘和油松的耐旱性较强,同时油松在各种土壤水分下其生长速度和干物质生产均显著低于其它3个树种;刺槐和84k杨树的耗水量、生物量及水分利用率在3种土壤水分下均显著高于沙棘和油松,84k杨树和刺槐均属于高耗水树种;研究结果表明。84k杨树和刺槐不适宜大面积栽植在黄土高原缺水地区,仅适合栽植在阴坡、沟道等适宜水分条件下。沙棘和油松则适宜栽植在土壤水分较低的地区,如阳坡、峁顶等立地条件上。     

辽西半干旱区几种人工林生态系统涵养水源功能研究

从森林生态系统树冠截留降雨、枯落物持水及土壤蓄水3个层次对辽西半干旱区5种人工林生态系统的涵养水源功能进行了定量研究．结果表明,各人工林生态系统树冠对降雨的平均截留率为14．58％～37．19％,依次为沙棘林>油松沙棘混交林>杨树沙棘混交林>油松纯林>杨树纯林;枯落物层厚度为1．6～4．1cm,枯落物贮量为1890．4～6425．2kg·hm^-2,枯落物层厚度和贮量均为沙棘林>油松沙棘混交林>杨树沙棘混交林>油松纯林>杨树纯林,枯落物最大持水量取决于枯落物贮量及其最大持水率,枯落物最大持水量为5957．7～19332．9kg·hm^-2,依次为沙棘林>油松沙棘混交林>杨树沙棘混交林>油松纯林>杨树纯林;各人工林生态系统0～40cm土壤层非毛管蓄水量为23．70～37．85mm,依次为沙棘林>杨树沙棘混交林>油松沙棘混交林>杨树纯林>油松纯林．在5种人工林生态系统中,沙棘林的涵养水源功能最好,混交林较油松和杨树纯林有更好的涵养水源功能．     

半干旱黄土区成熟柠条林地土壤水分利用及平衡特征

选择半干旱黄土区流域尺度不同地形条件下成熟柠条林作为研究对象,并以荒坡草地作为对照,在2009—2011年生长季节对0—210cm土壤含水量进行连续观测,开展了剖面土壤水分变异、动态平衡及影响因素研究。结果显示:土壤水分平均值:30—130cm对照>北坡>东坡>南坡,150—210cm南坡(上、中坡位)>对照>北坡>东坡,南坡和北坡样地上坡位>中坡位>下坡位。土壤水分的季节变化表现为9月﹥8月﹥7月,5、6、10月份最低;不同地形条件下,柠条林地土壤水分极差值和变异系数并没呈现出规律性变化,在垂直尺度上,柠条林地土壤水分极差值和变异系数曲线在0—50cm表现比较活跃,70—210cm则相对稳定;在连续干旱年份土壤储水量并没有连续的降低和亏缺,在第1个欠水年亏缺比较严重,第2个欠水年盈亏量基本平衡,而第3个欠水年则略有盈余。研究认为:小流域尺度下的地形条件差异造成了土壤水分规律性变化,但在特定植被生长发育状态和剖面尺度下,植被因子将会成为土壤水分动态变化的主控因子。柠条林发育至成熟阶段,土壤水分补偿与消减将会保持平衡状态。土壤水分与植被生长的相互关系一方面表现出一定的时间差,另一方面植被对土壤水分也具有一定的适应性。这是因为土壤含水率高促进植物生长,植物生长势增强会进一步加大对土壤水分的消耗,土壤水分含量不足则会抑制植物生长,植物生长势减弱会进一步降低对土壤水分的消耗。     

皇甫川流域柠条林地水分动态模拟——坡度、坡向、植被密度与土壤水分的关系

在皇甫川流域,随着林草覆盖度的增加,植被与水的矛盾日益突出,其中一个重要的问题就是植被密度与土壤水分之间的矛盾。土壤水分的降低影响了植被的生长,甚至导致了部分植被的死亡,因此对土壤水分与植被密度之间的关系进行研究非常重要,有助于合理造林密度的确定。在已有研究及实验观测的基础上,建立了柠条(Caragana intermedia)林地土壤水分动态模拟模型,模型考虑了主要的土壤、植物过程,包括土壤性状、降雨入渗、植物蒸腾、地表蒸发等;模拟了从1971至2000年,30年里各种立地条件(不同盖度、坡向和坡度)下的柠条林地土壤水分、蒸腾和蒸发等的日动态过程。通过比较不同立地条件下的土壤水分动态,研究了皇甫川流域典型柠条林地土壤水分与植被盖度、坡向和坡度之间的关系,并得出了它们之间的关系式。由得到的平地上柠条的适宜密度,同时结合上述关系式,得出了不同坡度、坡向的适宜密度。坡度小于10°时,适宜造林密度对坡度反应敏感,在10°~30°时,适宜盖度对坡度反应不敏感。对于小于10°的坡地,植被建设时要特别注意设计合理的植被密度。     

水蚀风蚀交错区典型植被土壤水分消耗和补充深度对比研究

研究了黄土高原水蚀风蚀交错区六道沟小流域8种植被类型条件下植物消耗土壤水分深度与降水对应的补充深度。结果表明:裸地、农地、撂荒地、人工草(灌)地(苜蓿地、柠条地、沙打旺地)、当地典型草地(荒草地、长芒草地)在平水年及干旱年,土壤水分均表现为负平衡;丰水年部分样地土壤水分得到补充。平水年以及干旱年(2010—2011年)植物耗水深度依次为:柠条地撂荒地沙打旺地苜蓿地≈长芒草地≈荒草地农地裸地,降水补充深度为农地裸地撂荒地荒草地长芒草地沙打旺地苜蓿地柠条地。丰水年(2012年)裸地、苜蓿地、荒草地与沙打旺地土壤水分并未显示出明显负平衡过程,但柠条地耗水深度依然达到260 cm,其它样地依次为撂荒地农地长芒草地;降水入渗深度排序:农地裸地撂荒地=柠条地荒草地=苜蓿地长芒草地沙打旺地。水蚀风蚀交错区土壤蒸发(裸地蒸发)以及降水补充深度一般为0—120 cm范围内,丰水年土壤水分能得到恢复。农地的土壤水分消耗与补充深度略有增加。农地撂荒后耗水深度与撂荒地植被类型有密切联系,随植被盖度与丰度的增加,耗水有进一步加深的趋势,撂荒地土壤水分补充深度小于等于消耗深度。农地退耕还草所种植的深根性植被(苜蓿、沙打旺、柠条等)不仅会迅速消耗当季降水,同时会进一步消耗土壤深层储水,致使120 cm以下观测土层土壤含水量较低,造成土壤水分消耗深度较浅的假象。除撂荒地外,高生物产量的人工草(灌)耗水量高,耗水深度也深,因此在退耕还林(草)过程中,应该充分考虑不同植被类型的年度水分交换深度,采取措施降低消耗深度,增加入渗深度。     

不同程度的水分胁迫对沙棘幼苗生理生态特征的影响

为探讨未来降水减少对内蒙古皇甫川流域沙棘幼苗生理生态特征的影响,特设计平均降雨水平、偏旱、干旱和极端干旱4种不同的水分梯度处理,开展人工水分梯度实验。方差分析表明,不同的水分梯度显著影响土壤的含水量、土壤温度等微生境因子,并显著影响净光合速率、气孔导度、蒸腾速率等气体交换特征、资源利用效率和叶片水势特征。适度的水分胁迫(干旱环境)能够提高沙棘的水分利用效率,同时却降低净光合速率和蒸腾速率。各种生理生态指标表明,4种水分处理的沙棘幼苗都受到不同程度的水分胁迫的影响,极端干旱环境中沙棘幼苗的内在生理调节机制出现紊乱,皇甫川流域沙棘不适宜在极端干旱环境中生长。     

不同程度的水分胁迫对沙棘幼苗生理生态特征的影响

为探讨未来降水减少对内蒙古皇甫川流域沙棘幼苗生理生态特征的影响,特设计平均降雨水平、偏旱、干旱和极端干旱4种不同的水分梯度处理,开展人工水分梯度实验.方差分析表明,不同的水分梯度显著影响土壤的含水量、土壤温度等微生境因子,并显著影响净光合速率、气孔导度、蒸腾速率等气体交换特征、资源利用效率和叶片水势特征.适度的水分胁迫(干旱环境)能够提高沙棘的水分利用效率,同时却降低净光合速率和蒸腾速率.各种生理生态指标表明,4种水分处理的沙棘幼苗都受到不同程度的水分胁迫的影响,极端干旱环境中沙棘幼苗的内在生理调节机制出现紊乱,皇甫川流域沙棘不适宜在极端干旱环境中生长.     

提高CO2浓度对两种亚热带树苗叶片水分状况的影响

鼎湖山季风常绿阔叶林的主要优势乔木树种黧蒴和荷木的幼苗,盆栽于自然光照和人工调节CO₂浓度为500μl·L^-1或空气CO₂(340μl·L^-1)的气罩中3个月.在各自生长条件下测定,高CO₂下生长的黧蒴和荷木叶片平均气孔导度分别降低13%和20%,蒸腾速率下降20%和18%,水分利用效率提高1倍以上,不同CO₂浓度下的植物叶片气孔导度和蒸腾速率日进程曲线也有明显差异.处理后将幼苗置于自然条件下观测其后效应,第7d时处理间的气孔导度和蒸腾速率皆无明显差异     

Diurnal courses and factorial dependencies of leaf conductance and transpiration of differently potassium fertilized and watered field grown barley plants

During the grain filling period we followed diurnal courses in leaf water potential (ψ₁), leaf osmotic potential (ψ_π), transpiration (E), leaf conductance to water vapour transfer (g) and microclimatic parameters in field-grown spring barley (Hordeum distichum L. cv. Gunnar). The barley crop was grown on a coarse textured sandy soil at low (50 kg ha⁻¹) or high (200 kg ha⁻¹) levels of potassium applied as KCl. The investigation was undertaken at full irrigation or under drought. Drought was imposed at the beginning of the grain filling period. Leaf conductance and rate of transpiration were higher in the flag leaf than in the leaves of lower insertion. The rate of transpiration of the awns on a dry weight basis was of similar magnitude to that of the flag leaves. On clear days the rate of transpiration of fully watered barley plants was at a high level during most part of the day. The transpiration only decreased at low light intensities. The rate of transpiration was high despite leaf water potentials falling to rather low values due to high evaporative demands. In water stressed plants transpiration decreased and midday depression of transpiration occurred. Normally, daily accumulated transpirational water loss was lower in high K leaves than in low K leaves and generally the bulk water relations of the leaves were more favourable in high K plants than in low K plants. The factorial dependency of the flag leaf conductances on leaf water potential, light intensity, leaf temperature, and leaf-to-air water vapour concentration difference (ΔW) was analysed from a set of field data. From these data, similar sets of microclimatic conditions were classified, and dependencies of leaf conductance on the various environmental parameters were ascertained. The resulting mathematical functions were combined in an empirical simulation model. The results of the model were tested against other sets of measured data. Deviations between measured and predicted leaf conductance occurred at low light intensities. In the flag leaf, water potentials below-1.6 MPa reduced the stomatal apertures and determined the upper limit of leaf conductance. In leaves of lower insertion level conductances were reduced already at higher leaf water potentials. Leaf conductance was increased hyperbolically as photosynthetic active radiation (PAR) increased from darkness to full light. Leaf conductance as a function of leaf temperature followed an optimum curve which in the model was replaced by two linear regression lines intersecting at the optimum temperature of 23.4°C. Increasing leaf-to-air water vapour concentration difference caused a linear decrease in leaf conductance. Leaf conductances became slightly more reduced by lowered water potentials in the low K plants. Stomatal closure in response to a temperature change away from the optimum was more sensitive in high K plants, and also the decrease in leaf conductance under the influence of lowered ambient humidity proceeded with a higher sensitivity in high K plants. Thus, under conditions which favoured high conductances increase of evaporative demand caused an about 10% larger decrease in leaf conductance in the high K plants than in the low K plants. Stomatal sizes and density in the flag leaves differed between low and high K plants. In plants with partially open stomata, leaf conductance, calculated from stomatal pore dimensions, was up to 10% lower in the high K plants than in the low K plants. A similar reduction in leaf conductance in high K plants was measured porometrically. It was concluded that the beneficial effect of K supply on water use efficiency reported in former studies primarily resulted from altered stomatal sizes and densities.     

Phosphorus concentrations in the leaves of defoliated white clover affect abscisic acid formation and transpiration in drying soil

Increased leaf phosphorus (P) concentration improved the water-use efficiency (WUE) and drought tolerance of regularly defoliated white clover plants by decreasing the rate of daily transpiration per unit leaf area in dry soil. Night transpiration was around 17% of the total daily transpiration. The improved control of transpiration in the high-P plants was associated with an increased individual leaf area and WUE that apparently resulted from net photosynthetic assimilation rate being reduced less than the reductions in the transpiration (27% vs 58%). On the other hand, greater transpiration from low-P plants was associated with poor stomatal control of transpirational loss of water, less ABA in the leaves when exposed to dry soil, and thicker and smaller leaf size compared with high-P leaves. The leaf P concentration was positively related with leaf ABA, and negatively with transpiration rates, under dry conditions ( P < 0.001). However, leaf ABA was not closely related to the transpiration rate, suggesting that leaf P concentration has a greater influence than ABA on the transpiration rates.     

Types of the daily course of transpiration rate in seedlings of forest trees

Types of the daily course of transpiration rate were studied in two-year old seedlings ofPinus silvestris L.,Picea excelsa L.,Larix decidua L.,Tilia cordata Mill., andAlnus glu-tinosa (L.) Gaertn. The curves illustrating the daily development of transpiration rate (Figs. 3 - 8) may be grouped in two types, showing a midday maximum (one-peak curves) and a midday depression (two-peak curves). Unlike herbaceous plants, the seedlings ofPinus silvestris L. were found to show, during the night-time, lower but not negligible values for the rate of transpiration (see Figs. 3 and 8). The following times are considered most suitable in determining the rate of transpiration for both herbs and woody species during the daylight: 09.0, 12.0, 14.0, and 17.0 hours. For the forest species seedlings further times are suitable for the night-time, as follows: 23.0, 01.0, and 06.0 hours. The rate of transpiration in the seedlings of Pinus silvestris attained very low levels at 3 and between 6 and 8 a.m. and between 6 and 8 p.m. (see Figs 3 and 8).     

Changes in Transpiration, Net Carbon Dioxide Assimilation and Leaf Water Potential Resulting from Application of Hydrostatic Pressure to Roots of Intact Pepper Plants

Hydrostatic pressures varying from 0 to 6.0 bar were applied to roots of intact Capsicum annuum L. cv. California Wonder plants growing in nutrient solution and the rates of transpiration, and net CO₂ assimilation, apparent compensation point and leaf water potential measured. Increasing the pressure on the roots of plants with roots in solution with either -0.5 or -5.0 bar osmotic potential with 1 bar increments resulted in a decrease in transpiration. With the application of 1 or 2 bar pressure the rate of transpiration returned to near or above the original rate. An application of 3 or 4 bar pressure reduced the rate of transpiration of all plants. The transpiration of plants with roots in solution with -0.5 bar osmotic potential remained at the reduced rate for as long as these pressures were maintained. The transpiration of plants with roots in solution with -5.0 bar was only temporarily suppressed at these pressures. Changing the applied pressure from 3 or 4 bar to 0 resulted in a rapid increase in transpiration which lasted approximately 15 minutes. This was followed by a decrease in transpiration to a rate lower than before the pressure was applied. The pattern of response was similar for plants at low or high light intensity or at normal or low CO₂ concentrations. When leaf diffusive resistance was 6.0 s cm^?1 or greater, changes in net CO₂ assimilation were similar to those of transpiration. The apparent CO₂ compensation point increased as pressure was applied and decreased with a release in pressure. Leaf water potential increased with an increase in pressure and decreased with a decrease in pressure. The changes in leaf water potential were frequently but not always proportional to changes in pressure. It is postulated that the respouses noted were due to changes in resistance to flow of water from xylem terminals through the mesophyll cells and stomatal cavities to the atmosphere.     

Responses of transpiration and hydraulic conductance to root temperature in nitrogen- and phosphorus-deficient cotton seedlings

Suboptimal N or P availability and cool temperatures all decrease apparent hydraulic conductance (L) of cotton (Gossypium hirsutum L.) roots. The interaction between nutrient status and root temperature was tested in seedlings grown in nutrient solutions. The depression of L (calculated as the ratio of transpiration rate to absolute value of leaf water potential [Ψ_w]) by nutrient stress depended strongly on root temperature, and was minimized at high temperatures. In fully nourished plants, L was high at all temperatures ≥20°C, but it decreased greatly as root temperature approached the chilling threshold of 15°C. Decreasing temperature lowered Ψ_w first, followed by transpiration rate. In N- or P-deficient plants, L approached the value for fully nourished plants at root temperatures ≥30°C, but it decreased almost linearly with temperature as roots were cooled. Nutrient effects on L were mediated only by differences in transpiration, and Ψ_w was unaffected. The responses of Ψ_w and transpiration to root cooling and nutrient stress imply that if a messenger is transmitted from cooled roots to stomata, the messenger is effective only in nutrient-stressed plants.     

峰丛洼地恢复演替系列优势种光合生理生态特征日变化研究——以广西马山弄拉峰丛洼地为例

运用LI-6400便携式光合测定系统,测定弄拉峰丛洼地不同演替阶段优势种白茅、黄荆、红背山麻杆、黄杞和青冈的光合生理生态特性,并比较它们的净光合作用速率、蒸腾作用速率、气孔导度、水分利用效率、表观量子效率等生理生态指标及其生境中对应的光合有效辐射、大气CO2浓度、气温、相对湿度的日变化。结果表明,峰丛洼地生态环境因子日变化复杂,黄杞有明显的"午休"现象,先锋种黄荆、红背山麻杆的净光合作用速率、蒸腾速率和气孔导度较大,先锋种中C4植物白茅水分利用效率最高,演替后期优势种青冈和黄杞的表观光量子效率、利用岩溶区水分的效率和适应性更强。对净光合作用速率与生理生态影响因子进行相关性分析,表明生理和生态因子共同影响植物的光合作用,不同演替优势种的影响因子有差异。以逐步回归方式建立净光合作用速率和影响因子之间的回归方程模型,5个方程均有显著性意义和良好的预测性。     

植物根系水力再分配模型参数分析与尺度转换

植物根系水力再分配(Hydraulic redistribution)是近几年提出的对植物根系水力提升现象一种更准确的描述。Ryel等(2002)建立的根系水力再分配模型(以下简称Ryel模型)模拟结果表明根系水力再分配是土壤水分动态的一个重要组成部分。该文基于Ryel模型,对模型中涉及的重要参数进行敏感性分析,更准确地阐述参数变化下根系水力再分配模型的行为动态,从而定量分析环境及植物自身等因素对根系水力再分配的影响。Ryel模型时间尺度和土层厚度的设定限制了模型的应用,该文通过参数调整,将模型从时间尺度为小时、土层厚度均一转换到时间尺度为天、土层厚度不等,并应用到内蒙古皇甫川流域。