花棒茎流对降雨的响应

干旱半干旱区植物生理过程的水分响应依赖于降雨强度和频率,研究典型沙生植物对降雨的响应有助于预测未来气候条件下荒漠生态系统的结构和功能变化.2012和2013年花棒生长季,在宁夏盐池采用包裹式茎流仪对花棒茎流进行连续观测,分析茎流在晴天和雨天的变化特征及其对不同降雨事件的响应.结果表明: 雨天的花棒日茎流量低于晴天.晴天,茎流日变化呈“几”字型宽峰曲线,与太阳辐射和相对湿度呈正相关;雨天,茎流日变化呈多峰曲线或者一直处于极低状态,与太阳辐射和空气温度呈正相关.降雨不仅可以通过影响当天太阳辐射、空气温度、饱和蒸汽压差和相对湿度影响花棒茎流通量,还通过调控土壤含水量影响降雨后的茎流通量.降雨量<20 mm时,降雨前后茎流通量差异不显著;降雨量>20 mm时,降雨后的茎流通量比降雨前有显著提高.高土壤含水量不仅能够提高茎流通量,并且能够提高茎流通量对太阳辐射、饱和水汽压差和空气温度的响应敏感性.     

花棒茎流对降雨的响应

干旱半干旱区植物生理过程的水分响应依赖于降雨强度和频率,研究典型沙生植物对降雨的响应有助于预测未来气候条件下荒漠生态系统的结构和功能变化.2012和2013年花棒生长季,在宁夏盐池采用包裹式茎流仪对花棒茎流进行连续观测,分析茎流在晴天和雨天的变化特征及其对不同降雨事件的响应.结果表明: 雨天的花棒日茎流量低于晴天.晴天,茎流日变化呈“几”字型宽峰曲线,与太阳辐射和相对湿度呈正相关;雨天,茎流日变化呈多峰曲线或者一直处于极低状态,与太阳辐射和空气温度呈正相关.降雨不仅可以通过影响当天太阳辐射、空气温度、饱和蒸汽压差和相对湿度影响花棒茎流通量,还通过调控土壤含水量影响降雨后的茎流通量.降雨量<20 mm时,降雨前后茎流通量差异不显著;降雨量>20 mm时,降雨后的茎流通量比降雨前有显著提高.高土壤含水量不仅能够提高茎流通量,并且能够提高茎流通量对太阳辐射、饱和水汽压差和空气温度的响应敏感性.     

Effect of High Flow Events on In-Stream Dissolved Organic Nitrogen Concentration

Dissolved organic nitrogen (DON) can comprise a large and biologically important fraction of total dissolved N in surface water. Biotic and abiotic processes result in heterogeneous DON concentrations and bioavailability in soils, and as hydrologic connectivity expands and flow paths change in watersheds, novel sources of DON can be mobilized and transported to surface water. Although the relationship between in-stream DOC concentration and stream discharge has previously been examined in the literature, up to now there has not been a synthesis examining how DON concentrations, loads, and composition change during transitions from base flow to pulse flow conditions. We present a meta-analysis examining the effect of high flow on DON concentration ([DON]). The ratio of mean pulse flow [DON] to mean base flow [DON] (P:B) was calculated for individual events and averaged (geometric) within and then across sites to generate an overall effect size. For 47 sites (78 events), mean P:B was 1.58, which was significantly different from unity. This moderate increase in DON concentration contributed to over a more than 10-fold average increase in the rate of DON yield from base flow to high flow. The response of [DON] to high flow was significant in catchments where individual storm events or snowmelt runoff events were responsible for elevated flows, whereas the response was not significant in catchments where high discharge resulted from a mixture of upstream snowmelt and rain events. Additionally, an examination of DOC:DON ratios during high flow indicates that multiple sources of DON may be mobilized during high flow. Finally, current models of annual DON export may be improved by including a positive relationship between discharge and DON.     

Does the severity of non‐flow periods influence ecosystem structure and function of temporary streams? A mesocosm study

相似文献   

社区尺度绿色基础设施暴雨径流消减模拟研究

当前快速的城市化进程导致了城市地区内涝事件频繁发生。绿色基础设施是减轻城市洪涝的有效措施之一。SWMM(Storm Water Management Model)等模型的复杂性使得规划管理者对模型的操作和应用存在困难,而且缺乏对绿色基础设施径流消减机制的展现。目前的研究中,比较单个与综合绿色基础设施配置径流消减效果的研究相对较少。基于水量平衡和城市水文过程,开发了社区尺度绿色基础设施消减作用的暴雨径流模型,并以北京市一典型社区为例,模拟研究了一年一遇和五年一遇两种暴雨条件下不同绿色基础设施配置对暴雨径流流量和峰值的消减效率。结果表明:用两场野外监测的降雨和径流数据验证模型得到的决定系数分别为0.68和0.71,纳什效率系数分别达到0.99和0.96,表明模型是可靠的。在一年一遇和五年一遇两种暴雨条件下,将常规绿地改造成5 cm深度的下凹式绿地,径流量分别减少了8.23%和23.30%,径流峰值分别减少了20.31%和29.11%;在建造300 m3调蓄池的情景下,径流量分别减少了84.90%和20.97%,径流峰值分别减少了88.99%和0.10%;在50%的不透水地表铺装透水砖情景下,径流量分别减少了46.51%和38.52%,径流峰值分别减少了39.96%和35.48%。3种绿色基础设施都可以较好的消减社区暴雨径流,但是随着暴雨强度的增强,下凹式绿地的消减效果略增强,调蓄池的消减效果变差,透水砖铺装的消减效果较稳定。综合3种措施对暴雨径流具有显著消减效果,可以100%消减一年一遇暴雨产生的径流,在五年一遇设计暴雨条件下,分别消减75.47%的总径流量和64.52%的径流峰值。     

Rain events decrease boreal peatland net CO2 uptake through reduced light availability

Boreal peatlands store large amounts of carbon, reflecting their important role in the global carbon cycle. The short‐term exchange and the long‐term storage of atmospheric carbon dioxide (CO₂) in these ecosystems are closely associated with the permanently wet surface conditions and are susceptible to drought. Especially, the single most important peat forming plant genus, Sphagnum, depends heavily on surface wetness for its primary production. Changes in rainfall patterns are expected to affect surface wetness, but how this transient rewetting affects net ecosystem exchange of CO₂ (NEE) remains unknown. This study explores how the timing and characteristics of rain events during photosynthetic active periods, that is daytime, affect peatland NEE and whether rain event associated changes in environmental conditions modify this response (e.g. water table, radiation, vapour pressure deficit, temperature). We analysed an 11‐year time series of half‐hourly eddy covariance and meteorological measurements from Degerö Stormyr, a boreal peatland in northern Sweden. Our results show that daytime rain events systematically decreased the sink strength of peatlands for atmospheric CO₂. The decrease was best explained by rain associated reduction in light, rather than by rain characteristics or drought length. An average daytime growing season rain event reduced net ecosystem CO₂ uptake by 0.23–0.54 gC m^?2. On an annual basis, this reduction of net CO₂ uptake corresponds to 24% of the annual net CO₂ uptake (NEE) of the study site, equivalent to a 4.4% reduction of gross primary production (GPP) during the growing season. We conclude that reduced light availability associated with rain events is more important in explaining the NEE response to rain events than rain characteristics and changes in water availability. This suggests that peatland CO₂ uptake is highly sensitive to changes in cloud cover formation and to altered rainfall regimes, a process hitherto largely ignored.     

基于涡度相关法和树干液流法评价杨树人工林 生态系统蒸发散及其环境响应

 运用涡度相关(Eddy covariance)开路系统、树干液流(Sap flow)、土壤水分以及微气象观测系统, 于2006年生长季(5~10月)对北京大兴区永定河沿河沙地杨树(Populus euramericana)人工林生态系统的水量和能量平衡进行了连续测定; 分析了该系统能量平衡闭合水平及其组分分配特征, 不同水分条件下蒸发散及其各组分变化过程和分配特征, 以及影响蒸发散的主要环境因子; 并对组分求和法、土壤水分平衡法与涡度相关法测得该生态系统生长季蒸发散总量的结果进行了对比。结果表明: 生长季内该生态系统的能量闭合水平较高, 能量平衡各组分在不同土壤水分环境条件下所占比例变化较大; 在水分充足的条件下, 潜热通量在可利用能量分配过程中占优势, 显热通量在水分胁迫条件下占可提供能量的比例比潜热通量大。雨季到来之前, 土壤蒸发与植被蒸腾强度相差较小; 进入雨季后, 土壤深层水分得到补偿, 植被蒸腾显著增强而土壤蒸发强度减弱。涡度相关法所得的总蒸发散量与基于树干液流法等组分求和法得到的蒸发散结果较接近, 分别为513和492 mm。土壤水分平衡法的观测结果略高于前二者的观测结果, 雨季研究界面以下的土体也有水分交换是该方法高估蒸发散的主要原因。与环境因子的响应关系表明, 蒸发散以及蒸腾的变化过程对净辐射的响应程度比对饱和水汽压差高; 水分条件较好情况下, 蒸发散以及蒸腾的变化过程与水汽压差关系不明显, 说明水分充足时, 水汽压差不是蒸散强弱的限制因子。     

Redistribution of soil water by lateral roots mediated by stem tissues

Evidence is increasing to suggest that a major activity of roots is to redistribute soil water. Roots in hydraulic contact with soil generally either absorb or lose water, depending on the direction of the gradient in water potential between root and soil. This leads to phenomena such as "hydraulic lift" where dry upper soil layers drive water transfer from deep moist layers to the shallow rhizosphere and, after rain or surface irrigation, an opposite, downward water transfer. These transport processes appear important in environments where rainfall is strongly seasonal (e.g. Mediterranean-type climates). Irrigation can also induce horizontal transfers of water between lateral roots. Compared with transpiration, the magnitudes, pathways, and resistances of these redistribution processes are poorly understood. Field evidence from semi-arid eucalyptus woodlands is presented to show: (i) water is rapidly exchanged among lateral roots following rain events, at rates much faster than previously described for other types of hydraulic redistribution using sap flow methods; (ii) large axial flows moving vertically up or down the stem are associated with the horizontal transfer of water between roots on opposite sides of the stem. It appears that considerable portions of the stem axis become involved in the redistribution of water between lateral roots because of partial sectoring of the xylem around the circumference of these trees.     

True water constraint under a rainfall interception experiment in a Mediterranean shrubland (Northern Tunisia): confronting discrete measurements with a plant–soil water budget model

Increased drought length and intensity is expected in the Mediterranean basin under anthropogenic increase in atmospheric CO₂, leading to extreme events not yet encountered in the present climate variability. Understanding ecosystems responses and capturing peculiar ecophysiological processes related to these events have been investigated in the field by rainfall manipulation experiments. Quantifying the actual drought faced by the ecosystem under control and dry plots, or among experiments remain a key challenge for explaining functional impacts on plant growth. Full-profile soil water content can be tricky to assess in rocky soils, and time-consuming plant water potential measurements remain a discrete information unable to capture short rainfall pulses. We propose here to fully investigate the water budget of a total rainfall interception manipulation on a Mediterranean shrubland, coupled with a plant–soil water balance model. We could accurately simulate the seasonal course of plant water status, including small rainfall pulses. We then derived yearly estimates of water stress integral for each water treatment, leading to an estimate of 66–86 % increase of drought intensity for the dry treatment compared to the control. Comparing actual and expected plant water budget from simulations in the dry plots allowed to identify and quantify the impact of methodological issues related to rainfall interception experiments as side effects for intrusive rain drops and subsurface lateral water flow.     

Calcium delivery and storage in plant leaves: exploring the link with water flow

Calcium (Ca) is a unique macronutrient with diverse but fundamental physiological roles in plant structure and signalling. In the majority of crops the largest proportion of long-distance calcium ion (Ca(2+)) transport through plant tissues has been demonstrated to follow apoplastic pathways, although this paradigm is being increasingly challenged. Similarly, under certain conditions, apoplastic pathways can dominate the proportion of water flow through plants. Therefore, tissue Ca supply is often found to be tightly linked to transpiration. Once Ca is deposited in vacuoles it is rarely redistributed, which results in highly transpiring organs amassing large concentrations of Ca ([Ca]). Meanwhile, the nutritional flow of Ca(2+) must be regulated so it does not interfere with signalling events. However, water flow through plants is itself regulated by Ca(2+), both in the apoplast via effects on cell wall structure and stomatal aperture, and within the symplast via Ca(2+)-mediated gating of aquaporins which regulates flow across membranes. In this review, an integrated model of water and Ca(2+) movement through plants is developed and how this affects [Ca] distribution and water flow within tissues is discussed, with particular emphasis on the role of aquaporins.     

Precipitation Regime Shift Enhanced the Rain Pulse Effect on Soil Respiration in a Semi-Arid Steppe

The effect of resource pulses, such as rainfall events, on soil respiration plays an important role in controlling grassland carbon balance, but how shifts in long-term precipitation regime regulate rain pulse effect on soil respiration is still unclear. We first quantified the influence of rainfall event on soil respiration based on a two-year (2006 and 2009) continuously measured soil respiration data set in a temperate steppe in northern China. In 2006 and 2009, soil carbon release induced by rainfall events contributed about 44.5% (83.3 g C m⁻²) and 39.6% (61.7 g C m⁻²) to the growing-season total soil respiration, respectively. The pulse effect of rainfall event on soil respiration can be accurately predicted by a water status index (WSI), which is the product of rainfall event size and the ratio between antecedent soil temperature to moisture at the depth of 10 cm (r ² = 0.92, P<0.001) through the growing season. It indicates the pulse effect can be enhanced by not only larger individual rainfall event, but also higher soil temperature/moisture ratio which is usually associated with longer dry spells. We then analyzed a long-term (1953–2009) precipitation record in the experimental area. We found both the extreme heavy rainfall events (>40 mm per event) and the long dry-spells (>5 days) during the growing seasons increased from 1953–2009. It suggests the shift in precipitation regime has increased the contribution of rain pulse effect to growing-season total soil respiration in this region. These findings highlight the importance of incorporating precipitation regime shift and its impacts on the rain pulse effect into the future predictions of grassland carbon cycle under climate change.     

Bark water uptake promotes localized hydraulic recovery in coastal redwood crown

Coastal redwood (Sequoia sempervirens), the world's tallest tree species, rehydrates leaves via foliar water uptake during fog/rain events. Here we examine if bark also permits water uptake in redwood branches, exploring potential flow mechanisms and biological significance. Using isotopic labelling and microCT imaging, we observed that water entered the xylem via bark and reduced tracheid embolization. Moreover, prolonged bark wetting (16 h) partially restored xylem hydraulic conductivity in isolated branch segments and whole branches. Partial hydraulic recovery coincided with an increase in branch water potential from about ?5.5 ± 0.4 to ?4.2 ± 0.3 MPa, suggesting localized recovery and possibly hydraulic isolation. As bark water uptake rate correlated with xylem osmotic potential (R² = 0.88), we suspect a symplastic role in transferring water from bark to xylem. Using historical weather data from typical redwood habitat, we estimated that bark and leaves are wet more than 1000 h per year on average, with over 30 events being sufficiently long (>24 h) to allow for bark‐assisted hydraulic recovery. The capacity to uptake biologically meaningful volumes of water via bark and leaves for localized hydraulic recovery throughout the crown during rain/fog events might be physiologically advantageous, allowing for relatively constant transpiration.     

Responses of soil respiration to simulated precipitation pulses in semiarid steppe under different grazing regimes

Aims Precipitation pulses and different land use practices (such as grazing) play important roles in regulating soil respiration and carbon balance of semiarid steppe ecosystems in Inner Mongolia. However, the interactive effects of grazing and rain event magnitude on soil respiration of steppe ecosystems are still unknown. We conducted a manipulative experiment with simulated precipitation pulses in Inner Mongolia steppe to study the possible responses of soil respiration to different precipitation pulse sizes and to examine how grazing may affect the responses of soil respiration to precipitation pulses.Methods Six water treatments with different precipitation pulse sizes (0, 5, 10, 25, 50 and 100 mm) were conducted in the ungrazed and grazed sites, respectively. Variation patterns of soil respiration of each treatment were determined continuously after the water addition treatments.Important findings Rapid and substantial increases in soil respiration occurred 1 day after the water treatments in both sites, and the magnitude and duration of the increase in soil respiration depended on pulse size. Significantly positive relationships between the soil respiration and soil moisture in both sites suggested that soil moisture was the most important factor responsible for soil respiration rate during rain pulse events. The ungrazed site maintained significantly higher soil moisture for a longer time, which was the reason that the soil respiration in the ungrazed site was maintained relatively higher rate and longer period than that in the grazed site after a rain event. The significant exponential relationship between soil temperature and soil respiration was found only in the plots with the high water addition treatments (50 and 100 mm). Lower capacity of soil water holding and lower temperature sensitivity of soil respiration in the grazed site indicated that degraded steppe due to grazing might release less CO₂ to the atmosphere through soil respiration under future precipitation and temperature scenarios.     

Modelling hydration and photosystem II activation in relation to in situ rain and humidity patterns: a tool to compare performance of rare and generalist epiphytic lichens

A dynamic water and activity model was developed to assess how efficiently lichens can exploit in situ rain and humid air. The capacity to rehydrate and activate photosynthesis [i.e. photosystem II (PSII)] by these water sources was compared among four hydrophilic and one generalist epiphytic lichen. Hydration status, potential (instant activation) and realized (delayed activation) day‐light activity were simulated using a model based on species‐specific hydration, PSII activation characteristics and in situ water content for Platismatia norvegica in three microclimatic scenarios. The results showed that delayed PSII activation could have profound effects on lichens' ability to exploit environmental water sources. During rain, realized activity was reduced by 19, 34 and 56% compared to simulations assuming instant activation for three hydrophilic lichens in the driest microclimate. During humid air, the reduction was 81% for the most extreme species and scenario, because of slow hydration and low equilibrium water content. Many and brief hydration events may thus hamper species with slow activation and fast desiccation kinetics. No evidence of compensation by a ‘water‐holding’ morphology was observed among studied species. The developed model may provide a tool for identifying suitable habitats for long‐term persistence of lichens with physiological constraints.     

Seed dynamics linked to variability in movement of tidal water

Question: Community structure may be influenced by patterns of dispersed seeds (seed rain) because they contribute to the template of plant community development. We explored factors influencing seed rain in a system dominated by tidal water, where direction and magnitude of water flow are difficult to predict, unlike many other hydrochorous systems where water flow is directional. We posed three main questions: (1) are patterns in seed rain linked to effects of hydrodynamic variability; (2) do these patterns in seed rain reflect distribution of seed sources and seed production; and (3) what are the implications for the assembly of tidal communities? Location: Salt marshes on the Wadden island of Schier‐monnikoog, The Netherlands. Methods: Species compositions of vegetation, seed rain, seed production and driftlines along a chronosequence of communities were compared. We also studied seed movement by sowing Astroturf® mats with seeds and checking for seeds remaining after a single tidal inundation. Results: Storm surges had a significant effect on seed‐rain patterns as the highest density and diversity of captured seeds were found during a stormy period. Seed rain of the youngest communities was more influenced by storms than that of older communities. Patterns in seed rain generally followed similar patterns in the distribution of established plants, and seed production. Conclusions: Results suggested mostly local dispersal of seeds. However, there was some evidence of long‐distance dispersal occurring during storm surges in younger communities that are regularly inundated with tidal water. The possible role of seed retention in constraining community development, rather than dispersal per se, is further discussed.     

我国南方红壤区氮磷湿沉降对森林流域氮磷输出及水质的影响

持续高通量的氮、磷输入导致水体富营养化的问题已引起广泛关注。通过对江西省千烟洲香溪流域水样(常规水样,降雨后的地表径流以及雨水水样)的季节性监测,研究大气氮、磷湿沉降对森林流域氮、磷输出动态及水质的影响。结果表明:从2013年6月至2014年5月,香溪流域内氮、磷湿沉降通量分别为11.86 kg/hm~2和0.38 kg/hm~2,其中氮湿沉降主要集中在夏秋两季,占全年输入量的64%,而磷沉降主要集中在夏季,占全年输入量的43%,表现出明显的季节性差异;水体p H值(6.22—8.89)的变化范围较大,而且氮、磷的输出受土地管理(施肥方式)及降雨事件的影响较为明显,尤其在耕作期,总氮的输出量占全年氮输出总量的96.2%,而总磷的输出量占全年磷输出总量的61.4%;对4场不同强度降雨(按降雨强度从大到小)的氮、磷输出动态过程分析,发现不同强度的降雨对水体氮、磷的输出过程影响不同,在径流未形成前以及降雨强度达到暴雨级别时,降雨对流域水体氮、磷的稀释作用明显,而在大雨强度下水体磷的输出量明显高于其他降雨;研究期间,香溪流域内氮湿沉降对水体的贡献量为101.97 kg,磷湿沉降的贡献量为0.60 kg,4场降雨氮对流域水体的贡献量为4.46kg,占流域氮输出负荷的15.22%,磷对水体的贡献量为0.032kg,占流域磷输出负荷的0.85%。同时,根据营养状态指数(EI),发现流域水体全年处于中至富营养状态,而且研究期间水体氮、磷浓度均超过水体富营养化阈值(氮1.5 mg/L,磷0.15 mg/L),存在爆发水体富营养化的威胁。     

The fate of rainfall in a mallee and heath vegetated catchment in southern Western Australia

Mallee, a shrub-eucalypt association, once covered large areas of the cereal growing land in Western Australia. The hydrologic consequences of land development have been more than a doubling of water yield and increased deep drainage beyond the plant-root zone. The latter has led to large areas of soil salinization. The uncleared catchment studied was covered with mallee vegetation (65%) and a heath association (35%). Over 12 years of measurement, runoff from the catchment has averaged 0.025 mm per annum with a mean annual rainfall of 376 mm. Half of the runoff resulted from two major events totalling 0.15 mm. Since there was no evidence of groundwater accession in the catchment, the rainfall was balanced by evapotranspiration. Despite virtually no runoff from the whole catchment, considerable internal redistribution of surface water occurred, with localized overland flow in some areas as high as 7.7 mm from 30.9 mm of rainfall in one day. Rainfall penetrated rapidly under the mallee vegetation and the rate of penetration observed could not be achieved solely through the soil even if there was saturated flow. A typical stand of native mallee trees (Eucalyptus pileata and E. eremophila) in the catchment effectively redistributed 8% of the annual rain falling on the stand with 3% lost as interception and 5% going to stemflow. However, on an individual tree basis some 15% of the rain falling on the canopy was lost as intercepted water and 25% ran down the stem. The stemflow caused saturated conditions around the bole of the mallee and dye tracing showed that the water penetrated the soil via the annular pathways of the soil-root interface. Roots of mallee trees were found at 28 m depth and it is postulated that the mallees are adapted to the semi-arid environment by virtue of their ability to store water deep in the soil profile for use during the dry summer months.     

Phenological and reproductive responses of a semiarid shrub to pulsed watering

Climate models forecast the decrease in annual precipitation and more extreme events (i.e. fewer rainy days and longer drought periods between rainfall events) in Mediterranean ecosystems which may have important consequences for plant community dynamics. Water availability is the most limiting factor for plant performance in arid environments, where it is often highly pulsed, and discrete rainfall events interspersed with drought periods are the important components of the annual water supply. Therefore, relatively small changes in rainfall frequency can have strong effects on the plant communities. We tested the effects of fewer rain events on inflorescence and fruit phenology, and reproductive success of a Mediterranean shrub species from semiarid SE Spain in a glasshouse trial. We found that by changing patterns of water supply, we strongly altered soil drying cycles with consequences for Phagnalon saxatile life history. Inflorescence and fruit phenology were not affected, and no changes in the number of inflorescences, fruits or fruit set were recorded. However, individuals growing under lower rainfall frequency produced bigger shoots, and heavier fruits and seeds. Bigger fruits produced a higher number of seeds that were heavier and more viable and, therefore, produced more seedlings than plants growing in the control treatment. Higher reproductive success achieved by Phagnalon individuals under low watering frequency may have important consequences for community dynamics if larger but less frequent rain events lead to an increase in soil water availability: natural selection favours individuals making the greatest contribution to the next generation. Such advantages could change community composition, the spatial distribution of species and their interactions.     

Vegetation and fire history of a Chinese site in southern tropical Xishuangbanna derived from phytolith and charcoal records from Holocene sediments

Aim The aims of this paper are to reconstruct the vegetation and fire history over the past 2000 years in a well‐preserved rain‐forest area, to understand interactions between climate, fire, and vegetation, and to predict how rain forest responds to global warming and increased intensity of human activity. Location Xishuangbanna, south‐west China, 21–22° N, 101–102° E. Methods Phytolith (plant opal silica bodies) morphotypes, assemblages, and indices were used to reconstruct palaeovegetation and palaeoclimate changes in detail. Micro‐charcoal particles found in phytolith slides, together with burnt phytoliths and highly weathered bulliform cells, were employed to reconstruct a record of past fire occurrence. A survey of field sediments, lithology, and ¹⁴C dating were also employed. Results Phytoliths were divided into 11 groups and classified into 33 well‐described morphotypes according to their shape under light microscopy and their presumed anatomical origins and ecological significance. The phytolith assemblages were divided into six significant zones that reveal a complete history of vegetation changes corresponding to climate variation and fire occurrence. Phytolith assemblages and indices show that the palaeoclimate in the study area is characterized by the alternation of warm–wet and cool–dry conditions. Phytolith and charcoal records reveal that 12 fire episodes occurred. Comparison of burnt phytoliths with an aridity index (Iph) shows that fire episodes have a strong relationship with drought events. Main conclusions Our results indicate that fire occurrence in the tropical rain forest of Xishuangbanna is predominantly under the control of natural climate variability (drought events). Nearly every fire episode is coupled with a climatic event and has triggered vegetation composition changes marked by a pronounced expansion of grasses. This indicates that drought interacts with fire to exert a strong influence on the ecological dynamics of the rain forest. However, the impact of human activity in recent centuries is also significant. Our results are important for understanding the interactions between climate, fire, and vegetation, and for predicting how rain forest responds to global warming and increased human activity.     

鹤山丘陵草坡的水文特征及水量平衡

 在中国科学院鹤山丘陵综合开放实验站的草坡集水区对大气降水和径流进行了连续4年的观测,并于1994年对该集水区的蒸散进行了测定,结果表明：1)鹤山丘陵区年均降水量1761.37mm,大气降水有明显的干湿季之分,干季降水量占全年降水量的12.47％,湿季占87.53％。年均降水量中有62.24％可引起地表产流,即年均产流降水量1096.3mm。产流降水以中、小雨频度为大,但产流水量主要由大、暴雨供给。文中根据降雨量较大地区的降水、产流特征和规律,提出了产流降水和产流水量的概念。2)鹤山丘陵草坡集水区年总径流系数50.12％,地表径流系数17.33％。地表径流主要集中在湿季产生,与降水量呈二次抛物线型回归关系,与降水强度关系不大。3)1994年水量平衡各分量中,实际降水输入1841.55mm,年径流量970.28mm,径流系数52．69％,径流是系统的最大输出项;蒸散量851.56mm,意味着年降水收入中46.24％的水量以汽态形式返回了大气。蒸散的月变化呈双峰型,不同于降水的季节分配,径流的月变化则与降水同步。系统蓄水年变化量19.71mm,约占年降水量的1.07％,但其月变化却非常大,在一68～104mm之间。草坡集水区的水量平衡是一种收入对支出的补给和收支项目中可变性的动态平衡。4)鹤山丘陵草坡水热季节分配失衡、产流降水量和地表径流量大是这种退化生态系统恢复的3个限制因素;认为退化生态系统恢复过程中系统水量支出和蓄留方式的转变是退化生态系统的恢复机理之一。