Modeling the spatial–temporal dynamics of water use efficiency in Yangtze River Basin using IBIS model

Climate change alters regional water and carbon cycling, which has been a hot study point in the filed of climatology and ecology. As a traditionally “water-rich” region of China, Yangtze River Basin plays an important role in regional economic development and ecosystem productivity. However, the mechanism of the influence of climate change on water and carbon cycling has been received little attention. As a coupling indicator for carbon and water, the water use efficiency (WUE) is widely used, which indicates the water consumption for carbon sequestration in watershed and regional scale. A lot of studies showed that climate change has significantly affected the water resource and production of the ecosystems in Yangtze River Basin during the period of 1956–2006, when great climate variations were occurred. To better understand the alternation pattern for the relationship between water and carbon cycling under climate change at regional scale, the WUE and the spatiotemporal variations patterns were simulated in the study area from 1956 to 2006 by using the Integrated Biosphere Simulator (IBIS). The results showed that the WUE spatial pattern had the annual and seasonal variations. In general, the average annual WUE value per square meter was about 0.58 g C/kg H₂O in Yangtze River Basin. The high WUE levels were mainly distributed in the eastern area of Sichuan, western area of Jiangxi and Hunan, and the highest value reached 0.88 g C/kg H₂O. The lowest WUE’s were mainly located in the western area of Sichuan and Qinghai with the lowest values reaching to 0.36 g C/kg H₂O. The WUE in other regions mostly ranged from 0.5 to 0.6 g C/kg H₂O. For the whole study area, the annual WUE slowly increased from 1956 to 2006. The WUE in the upper reaches of Yangtze River increased based on the simulated temporal trends, which mainly located in the western area of the Sichuan Basin; the WUE of the middle reaches of Yangtze River had increased slightly from 1987 to 1996, and then decreased from 1996 to 2006; the lower reaches of Yangtze River always had smaller WUE’s than the average from 1956 to 2006. The spatiotemporal variability of the WUE in the vegetation types was obvious in the Yangtze River Basin, and it was depended on the climate and soil conditions, and as well the disturbance in its distribution areas. The temporal variations of WUE among different vegetation types had similar trends but different in values. The forest type had higher WUE than any other vegetation types ranging from 0.65 to 0.8 g C/kg H₂O. The WUE of shrubland ranged from 0.45 to 0.6 g C/kg H₂O. The WUE of tundra was the lowest, indicating the differences in plant physiology. The consistence of the spatial pattern of WUE with the NPP indicated that the regional production of Yangtze River Basin increased based on the water resources prompted and vegetation restoration. We found the drought climate was one of critical factor that impacts the alteration of WUE in Yangtze River Basin in the simulation.     

Modeling the spatial–temporal dynamics of water use efficiency in Yangtze River Basin using IBIS model

Climate change alters regional water and carbon cycling, which has been a hot study point in the filed of climatology and ecology. As a traditionally “water-rich” region of China, Yangtze River Basin plays an important role in regional economic development and ecosystem productivity. However, the mechanism of the influence of climate change on water and carbon cycling has been received little attention. As a coupling indicator for carbon and water, the water use efficiency (WUE) is widely used, which indicates the water consumption for carbon sequestration in watershed and regional scale. A lot of studies showed that climate change has significantly affected the water resource and production of the ecosystems in Yangtze River Basin during the period of 1956–2006, when great climate variations were occurred. To better understand the alternation pattern for the relationship between water and carbon cycling under climate change at regional scale, the WUE and the spatiotemporal variations patterns were simulated in the study area from 1956 to 2006 by using the Integrated Biosphere Simulator (IBIS). The results showed that the WUE spatial pattern had the annual and seasonal variations. In general, the average annual WUE value per square meter was about 0.58 g C/kg H₂O in Yangtze River Basin. The high WUE levels were mainly distributed in the eastern area of Sichuan, western area of Jiangxi and Hunan, and the highest value reached 0.88 g C/kg H₂O. The lowest WUE’s were mainly located in the western area of Sichuan and Qinghai with the lowest values reaching to 0.36 g C/kg H₂O. The WUE in other regions mostly ranged from 0.5 to 0.6 g C/kg H₂O. For the whole study area, the annual WUE slowly increased from 1956 to 2006. The WUE in the upper reaches of Yangtze River increased based on the simulated temporal trends, which mainly located in the western area of the Sichuan Basin; the WUE of the middle reaches of Yangtze River had increased slightly from 1987 to 1996, and then decreased from 1996 to 2006; the lower reaches of Yangtze River always had smaller WUE’s than the average from 1956 to 2006. The spatiotemporal variability of the WUE in the vegetation types was obvious in the Yangtze River Basin, and it was depended on the climate and soil conditions, and as well the disturbance in its distribution areas. The temporal variations of WUE among different vegetation types had similar trends but different in values. The forest type had higher WUE than any other vegetation types ranging from 0.65 to 0.8 g C/kg H₂O. The WUE of shrubland ranged from 0.45 to 0.6 g C/kg H₂O. The WUE of tundra was the lowest, indicating the differences in plant physiology. The consistence of the spatial pattern of WUE with the NPP indicated that the regional production of Yangtze River Basin increased based on the water resources prompted and vegetation restoration. We found the drought climate was one of critical factor that impacts the alteration of WUE in Yangtze River Basin in the simulation.     

Characters of Cysteine Endopeptidases in Wheat Endosperm during Seed Germination and Subsequent Seedling Growth

The endopeptidases （EPs） in wheat endosperm during seed germination and subsequent seedling growth were characterized by gradient-polyacrylamide gel electrophoresis with gelatin copolymerized into the gel. Four cysteine EPs （EP1, EP2, EP3 and EP4） were detected in wheat endosperm during the 7 d growth after seed imbibition. The results also showed that the activities of all of these EPs increased continuously, and EP2 first appeared and had the highest proteolytic activity among the four EPs in this experimental process. The optimum pH and temperature of all four EPs were 4.0 and 40.0 ~C. All EPs were completely inhibited by 25 μmol/L E-64 and had no good thermal stabilities, especially EP1. In addition, these EPs had different substrate specificities to albumins, globulins, gliadins and glutenins; the main storage proteins of mature wheat endosperm. Among them, EP2 had the highest proteolytic activities on globulins, gliadins and glutenins, and might be the most important and specific EP with potential to be tightly correlated with seedling development.     

Effects of Interaction Between Cadmium and Plumbum on Phytochelatins and Glutathione Production in Wheat （Triticum aestivum L.）

Phytochelatins (PCs) may function as a potential biomarker for metal toxicity. However, less attention has been paid to the effects of metal interactions on the production of PCs and glutathione (GSH), the most prominent cellular thiol. In the present study, the effects of interactions between cadmium (Cd) and plumbum (Pb) on the production of PCs and GSH were monitored over a period of 14 d in wheat (Triticum aestivum L.) tissues. The results showed that combination of Cd and Pb led to synergistic growth inhibition in wheat. Exposure to Cd or Pb increased levels of PCs in a concentration-, tissue-, and time-dependent manner. Cadmium was more effective that Pb in increasing PCs production. Compared with the effects of Cd or Pb alone on the production of PCs, the combination of Cd and Pb acted synergistically, resulting in an enhanced production of PCs. Cadmium also stimulated GSH production in a concentration-, tissue-, and time-dependent manner. However, Pb had no obvious effects on GSH levels. The combination of Pb and Cd antagonized GSH production over the course of the growth period. The results of the present study suggest that metal interactions should be considered in the application of PCs and GSH as potential biomarkers for the evaluation of metal toxicity.     

Effluxes of nitrous oxide,methane and carbon dioxide and their responses to increasing nitrogen deposition in the Gurbantünggüt Desert of Xinjiang,China北大核心CSCD

Aims Desert soils play an important role in the exchange of major greenhouse gas (GHG) between atmosphere and soil. However, many uncertainties existed in understanding of desert soil role, especially in efflux evaluation under a changing environment. Methods We conducted plot-based field study in center of the Gurbantünggüt Desert, Xinjiang, and applied six rates of simulated nitrogen (N) deposition on the plots, i.e. 0 (N0), 0.5 (N0.5), 1.0 (N1), 3.0 (N3), 6.0 (N6) and 24.0 (N24) g·m-2·a-1. The exchange rates of N2O, CH4 and CO2 during two growing seasons were measured for two years after N applications. Important findings The average efflux of two growing seasons from control plots (N0) were 4.8 μg·m-2·h-1, -30.5 μg·m-2·h-1 and 46.7 mg·m-2·h-1 for N2O, CH4 and CO2, respectively. The effluxes varied significantly among seasons. N0, N0.5 and N1 showed similar exchange of N2O in spring and summer, which was relatively higher than in autumn, while the rates of N2O in N6 and N24 were controled by time points of N applications. The uptake of CH4 was relatively higher in both spring and summer, and lower in autumn. Emission of CO2 changed minor from spring to summer, and greatly decreased in autumn in the first measured year. In the second year, the emission patterns were changed by rates of N added. N additions generally stimulated the emission of N2O, while the effects varied in different seasons and years. In addition, no obvious trends were found in the emission factor of N2O. The uptake of CH4 was not significantly affected by N additions. N additions did not change CO2 emissions in the first year, while high N significantly reduced the CO2 emissions in spring and summer of the second year, without affected in autumn. Structure equation model analysis on the factors suggested that N2O, CH4 and CO2 were dominantly affected by the N application rates, soil temperature or moisture and plant density, respectively. Over the growing seasons, both the net efflux and the global warming potential caused by N additions were small.     

The effect of ecological management in the upper reaches of Heihe River

Heihe River is the second largest inland river in northwest China which flows through Qinghai Province, Gansu Province and Inner Mongolia Autonomous Region. Because of the rapid development of social economy, the sharp increase of water utilization in the middle reaches and the aggravation of contradiction of supply and demand on water resources, the water to the lower reaches decreases and the ecological environment deteriorates constantly. According to the severe situation of ecology system depravation in Heihe River basin, Chinese government decided to invest 2.35 billion RMB to carry out 3 years ecological management in Heihe River basin from August in 2001. After 3 years ecological management, the depravation of ecological environment is controlled effectively. This paper researches the ecological management engineering in the upper reaches of Heihe River and evaluates the effect of the ecological management engineering. The methods of field sampling and measuring are used to obtain the index indicating the ecology change in the upper reaches of Heihe River in 2006. The effects of fencing grassland, fencing natural forest, and artificial afforestation to the ecology are evaluated. The result suggests that: Firstly, in fencing grassland area, the yield of grass had increased by 42–113%, average height of the grass had increased by 60–100%, and the degree of coverage had increased by 67–100%. Secondly, in fencing natural forests area, the degree of coverage had increased by 15–33%, the shade density had increased by 50–100%, average height had increased by 80–125%, and the crown size had increased by 63–186%. Thirdly, the growth increment of the trees in artificial afforestation area is bigger than that outside artificial afforestation area. In conclusion, ecological management leads to obvious ecological effect in the upper reaches of Heihe River.     

Community characteristics and population structure of Ferrocalamus strictus,a rare species in Mojiang,Yunnan, China北大核心CSCD

Aims As an endangered wild species with extremely small populations, Ferrocalamus strictus is narrowly distributed in South Yunnan with a small number of individuals. The survey of population structure and community characteristics of the wild population of F. strictus can facilitate understanding its endangered system and mechanisms and provide preliminary research basis for its protection. Methods We investigated the community and population structure of F. strictus, including species composition, population density, population survivorship curve and death factors by plot surveying and sampling. Important findings The community in which population of F. strictus is located in Mojiang has some characteristics of mountain rainforests in terms of appearance and species composition. The population density of F. strictus was 2.04 ind.·m–2. The survivorship curve of F. strictus was between Deevey-I and Deevey-II. The net proliferation rate (R0) of F. strictus population was 1.10, which indicates an expanding population of F. strictus. The death of F. strictus is caused by human logging, natural death, shoot degradation and insects feeding. Among them, artificial cutting accounts for the largest proportion. Ferrocalamus strictus is a species of forest bamboos distributed in the South Asian subtropics, which is a medium-sized bamboo species. Its internode length change suddenly from the base 3–4 nodes. The longest ones exceed 1 m, which ranks at the top of all bamboo species and is closely related to its adaptation to the tropical mountain rainforest environment. © Chinese Journal of Plant Ecology.     

连作土灭菌对葡萄根际土壤微生物群落功能的影响

In order to explore the correlation between soil microbial community function and plant growth, using 30 year continuous cropping soil of grapevines as research object, we studied the effects of sterilization of continuous cropping soil at different temperatures on the growth of grapevines and the microbial community function of rhizosphere soil. The results showed that plant height and stem diameter of grapevines grown in continuous cropping soil were lower than those in the other treatments. With the increasing sterilization temperature, the plant height and stem dia meter of grapevines increased. The ratio of bacteria to fungi in rhizosphere soil increased with the increasing sterilization temperature. The activity of rhizosphere microbes using carbon source was in order of continuous cropping soil sterilized at 100 ℃ > non continuous cropping soil > continuous cropping soil sterilized at 60 ℃ > continuous cropping soil. The regression analysis showed that amino acid (carbon source) in Biolog ECO plate had a significant correlation with microbial metabolic activity of rhizosphere soil. PCA analysis showed that lysine in root exudate had a highest contribution to the variance of principal components in each treatment, and it may play an important role in the obstacle of continuous cropping of grapevines.     

The effect of ecological management in the upper reaches of Heihe River

Heihe River is the second largest inland river in northwest China which flows through Qinghai Province, Gansu Province and Inner Mongolia Autonomous Region. Because of the rapid development of social economy, the sharp increase of water utilization in the middle reaches and the aggravation of contradiction of supply and demand on water resources, the water to the lower reaches decreases and the ecological environment deteriorates constantly. According to the severe situation of ecology system depravation in Heihe River basin, Chinese government decided to invest 2.35 billion RMB to carry out 3 years ecological management in Heihe River basin from August in 2001. After 3 years ecological management, the depravation of ecological environment is controlled effectively. This paper researches the ecological management engineering in the upper reaches of Heihe River and evaluates the effect of the ecological management engineering. The methods of field sampling and measuring are used to obtain the index indicating the ecology change in the upper reaches of Heihe River in 2006. The effects of fencing grassland, fencing natural forest, and artificial afforestation to the ecology are evaluated. The result suggests that: Firstly, in fencing grassland area, the yield of grass had increased by 42–113%, average height of the grass had increased by 60–100%, and the degree of coverage had increased by 67–100%. Secondly, in fencing natural forests area, the degree of coverage had increased by 15–33%, the shade density had increased by 50–100%, average height had increased by 80–125%, and the crown size had increased by 63–186%. Thirdly, the growth increment of the trees in artificial afforestation area is bigger than that outside artificial afforestation area. In conclusion, ecological management leads to obvious ecological effect in the upper reaches of Heihe River.     

基于遗传算法的人工神经网络模型在冬小麦根系分布预报中的应用

In this study, a controlled experiment of winter wheat under water stress at the seedling stage was conducted in soil columns in greenhouse. Based on the data gotten from the experiment, a model to estimate root length density distribution was developed through optimizing the weights of neural network by genetic algorithm. The neural network model was constructed by using forward neural network framework, by applying the strategy of the roulette wheel selection and reserving the most optimizing series of weights, which were composed by real codes.This model was applied to predict the root length density distribution of winter wheat, and the predicted root length density had good agreement with experiment data. The way could save a lot of manpower and material resources for determining the root length density distribution of winter wheat.     

作物群体CO2通量和水分利用效率的快速测定

In this paper,Eddy Correlation (EC) method was employed to measure the latent heat and CO₂ flux density and to calculate Water Use Efficiency (WUE) of winter wheat community in Yucheng district,Shandong Province in 1997.The results showed that the CO₂ flux density had an obvious diurnal change,with a maximum about1.5 mg·s^-1·m^-2,which appeared at about 9:00～10:00 am in general.The WUE of wheat community presented a fall trend from morning to afternoon,and the CO₂ flux density and WUE also had an obvious seasonal change,being lower in the early and late growth stages,and higher in the middle growth stage.The ranges of daily mean CO₂ flux density and WUE were 0.2～0.9 mg·s^-1·m^-2 and 5～20 gCO₂·kg^-1 H₂O,respectively.     

遮荫条件下绞股蓝光合作用特点的研究

在夏季遮荫条件下栽培绞股蓝的净光合速率日变化呈现不典型的双峰曲线,第1峰值出现在11：00时,达13．8μmolCO2·m^-2·S^-1日净光合速率达到176．97μmol CO2·m^-2,是强光下栽培的3．1倍;净光合速率和光量子通量密度呈正相关,相对湿度对净光合速率的影响小．强光下栽培绞股蓝。光合作用“午休”现象明显,净光合速率日变化呈现双峰曲线,第1峰值出现在10：00时,为3．0μmol CO2·m^-2·s^-1．第2峰值出现在14：00时,为1．25μmol CO2·m^-2·s^-1;相对湿度与净光合速率成正相关,对净光合速率的影响大．当光量子通量超过700μmol·m^-2·s^-1时,净光合速率与光量子通量密度呈负相关．在影响该植物蒸腾速率的诸多因子中,蒸腾速率和气孔导度之间的相关性最为显著．因此绞股蓝属于高度耐荫而怕光的植物．人工栽培应重点考虑光照因子．     

三江平原春小麦农田生态系统氧化亚氮通量特征

利用静态暗箱-气相色谱法对三江平原春小麦农田生态系统N2O排放通量进行连续2.5年的田间原位观测.结果表明:三江平原春小麦农田生态系统N2O排放通量具有较明显的季节变化和年际变化,并主要与年际间降水及田间水分管理差异有关;春小麦农田生态系统N2O排放日变化与气温及地下5 cm温度变化有关.生长期N2O的排放较强,休耕期N2O排放量显著下降,冰冻期N2O的排放较微弱,融冻时N2O排放缓慢增强.生长期N2O平均排放通量为0.190 mg.m-2.h-1,收割后到冰冻期间为0.077 mg.m-2.h-1,冻融期间为0.017 mg.m-2.h-1.     

不同耕作措施下冬小麦生长季农田二氧化碳排放通量及其与土壤温度的关系

利用长期定位试验研究了华北平原不同耕作措施下冬小麦生育期农田CO2排放通量,并对CO2排放通量和土壤温度进行了回归模拟.结果表明冬小麦生育期CO2排放速率表现为翻耕＞旋耕＞免耕,平均分别为343.69、337.54和190.47 mg·m-2·h-1.各处理冬小麦生育期CO2排放通量与土壤温度呈显著正相关;翻耕地CO2排放通量与10 cm地温相关性最高,旋耕地和免耕地则与10 cm和20 cm地温相关性较高.CO2排放通量和土壤温度呈指数函数关系(P＜0.01),利用10 cm地温对冬小麦生育期农田CO2排放通量进行估算表明,翻耕、旋耕和免耕地CO2排放分别为1.88、1.89和1.03 kg·m-2.     

若尔盖高原沼泽湿地与草地二氧化碳通量的比较

采用静止箱/气相色谱法,在2003—2005年的植物生长期对若尔盖高原沼泽湿地和草地的CO₂通量进行了对比观测.结果表明：若尔盖高原沼泽湿地和草地CO₂通量的平均值分别为203.22和323.03 mg·m^-2·h^-1,前者为后者的60%左右.沼泽湿地常年积水的环境条件限制了土壤中的植物残体、根系及有机物质的分解,是沼泽湿地CO₂通量低于草地并形成泥炭积累的重要因素.研究区沼泽湿地与草地CO₂通量的季节变化与气温变化呈正相关,峰值一般出现在7月和8月;其日变化也与气温呈正相关,峰值一般出现在11:00—17:00.5 cm深的土壤温度与CO₂通量的相关性高于10和15 cm深的土壤温度.     

黄土旱塬区不同覆盖措施对冬小麦农田土壤呼吸的影响

采用田间试验研究了黄土旱塬区不同覆盖措施下的冬小麦农田土壤呼吸日变化和季节变化特征.试验包括4个处理：作物生育期秸秆覆盖600 kg·hm^-2（M₆₀₀）、秸秆覆盖300 kg·hm^-2（M₃₀₀）、地膜覆盖（PM）和无覆盖处理（CK）.结果表明：冬小麦农田土壤呼吸速率从播种至返青之前呈下降趋势,处理间没有显著差异;越冬后土壤呼吸速率迅速提高,至拔节期最高.与CK相比,3个覆盖处理在越冬至成熟期间均显著促进了土壤CO₂的释放,其中PM与其他处理间的差异达到极显著水平.全生育期M₆₀₀和M₃₀₀处理土壤呼吸速率平均分别为1.47和1.52 μmol CO₂·m^-2·s^-1,较CK（1.38 μmol CO₂·m^-2·s^-1）分别提高了6.6%和10.2%;PM处理土壤呼吸速率平均为3.63 μmol CO₂·m^-2·s^-1,较CK提高了163%.CK处理土壤呼吸日变化呈单峰曲线,峰值出现在12：00左右,秸秆覆盖后峰值时间推迟到14：00左右;PM处理土壤呼吸日变化特征在拔节期与对照相似,在成熟期则呈双峰曲线,峰值分别出现在12：00和16：00左右.土壤呼吸速率与土壤温度和土壤水分分别呈指数和抛物线式相关.     

辽东楤木光合和蒸腾作用对光照和土壤水分的响应过程

应用CIRAS-2型便携式光合作用系统,测定了不同土壤含水量下辽东楤木光合作用与蒸腾作用的光响应过程,探讨了辽东楤木对光照环境和土壤水分的适应性.结果表明:辽东楤木的净光合速率(P_n)、蒸腾速率(T_r)和叶片水分利用效率(WUE)对光量子通量密度(PFD)的响应过程不同;在强光范围内(PFD 800～1 800 μmol·m^-2·s^-1),随着光强增加,辽东楤木的P_n变化较小,而T_r逐渐减小,WUE明显提高.辽东楤木的光饱和点(LSP)和光补偿点(LCP)分别在800和30 μmol·m^-2·s^-1左右,且受土壤含水量变化的影响较小;但其光合量子效率(Ф)和暗呼吸速率(R_d)受土壤含水量变化的影响较大.辽东楤木的P_n和WUE对土壤含水量的变化有明显的阈值响应,其高效用水的土壤相对含水量(RWC)在44％～79％;在此范围内,辽东楤木能同时获得较高的光合速率和水分利用效率.     

华北平原麦田土壤呼吸特征

采用静态箱／气相色谱(GC)法测定了华北平原典型冬小麦田的土壤呼吸速率、结果表明,土壤呼吸速率日变化呈单峰曲线,最高峰出现在13：00左右,最低点在凌晨4：00左右;冬小麦生长季土壤呼吸速率平均冬季较低,夏季较高,与地温的季节变化趋势基本一致;随氮肥用量增加土壤呼吸增强,但增幅不大．秸秆还田处理的土壤呼吸作用明显高于秸秆不还田处理和氮肥处理;土壤呼吸同地温存在着显著的指数关系,其中5cm地温同土壤呼吸相关性最好．不同处理、不同深度土层具有不同的Q10值,Q10值随土壤的性状、地温测量的深度和微生物活动的土层深度变化而改变,其本身是温度的函数,随着温度的升高,Q10值呈下降趋势;土壤呼吸与土壤水分的关系较弱,未表现出明显的规律性;冬小麦平均净光合速率与土壤呼吸速率呈相似的变化趋势。从小麦返青到腊熟,冬小麦田表现为CO2的汇．     

热带季节雨林冠层树种绒毛番龙眼的光合生理生态特性

采用Li-6400便携式光合作用测定仪,对西双版纳热带季节雨林冠层树种绒毛番龙眼成树树冠上、中、下3层叶片进行了测定,分析西双版纳热带季节雨林冠层树木的光合作用.结果表明,绒毛番龙眼成树具有喜光的光合特性,光饱和点较高(1 000～1 500 μmol·m^-2·s^-1),而光补偿点较低(7.7～15.3 μmol·m^-2·s^-1),对光环境有较强的适应和调节能力,光合有效辐射是影响绒毛番龙眼光合日进程的关键因子;12月,叶片处于成熟期,生长良好,光合能力较强,树冠上层净光合速率（P_n）日变化为单峰型,最大净光合速率（A_max）约为8.9 μmol CO₂·m^-2·s^-1;4月处于新老树叶更替期,光合能力下降,树冠上层P_n日变化为双峰型,中午出现“午休”现象,树冠上层A_max约为4.3 μmol CO₂·m^-2·s^-1;7月上、中层叶片P_n为单峰型,下层出现“午休”.如人为使CO₂浓度在短期内迅速升高,则绒毛番龙眼的P_n会增加,而气孔导度和蒸腾速率降低;CO₂浓度从400 μmol·mol^-1升高到800 μmol·mol^-1时,干季水分利用效率（WUE）提高约50%～100％,雨季WUE较低.     

不同土壤水分条件下紫藤叶片生理参数的光响应

测定了不同土壤湿度下2年生紫藤叶片光合速率（P_n）、蒸腾速率（T_r）及水分利用效率（WUE）等生理参数的光响应过程,探讨了紫藤正常生长发育所需的土壤水分和光照条件.结果表明:紫藤叶片的P_n、T_r及WUE对土壤湿度和光照强度的变化具有明显的阈值响应.维持紫藤正常生长（同时具有较高P_n和WUE）的土壤湿度范围为:体积含水量（W_v）15.3%～26.5%、相对含水量（W_r）46.4%～80.3%,最佳土壤湿度约为W_v 23.3%、W_r 70.6%.紫藤叶片对光照环境的适应性较强,在光合有效辐射强度（PAR）为600～1 600 μmol·m^-2·s^-1时,P_n和WUE具有较高水平,饱和光强在PAR为800～1 000 μmol·m^-2·s^-1.紫藤叶片光合作用非气孔限制的发生与土壤湿度与光照强度密切相关,W_v为18.4%～26.5%、W_r为55.8%～80.3%时,光合作用主要受气孔限制,光照强度的影响较小;超出此范围后,其受光照强度的影响较大,出现由气孔限制转变为非气孔限制的PAR临界值.紫藤正常生长允许的最低土壤湿度约为W_v 11.9%、W_r 36.1%,允许最高PAR约为1 000 μmol·m^-2·s^-1,是紫藤叶片光合机构受到破坏的临界点.