干热河谷印楝树干液流密度动态变化特征研究

采用TDP技术对金沙江干热河谷元谋段主要造林树种印楝的树干液流密度动态变化进行了观测,得到3点主要结论:①无论干热季节或湿润季节,印楝树干液流密度昼夜变化的规律性较强,呈明显的单峰曲线;②由干热季节转向湿润季节时,印楝树干液流密度呈下降趋势,5年生印楝在5月、7月及10月的典型晴天里的树干液流密度日变化平均值分别为12.11、7.48及6.90cm3·cm-2·h-1;③在干热季节里印楝蒸腾耗水具有相当的被动性,而在湿润季节时其蒸腾耗水则表现出主动性和平氨性,反映了印楝在不同季节里的耗水机制差异.     

Effects of planting density on the productivity and water use of tea (Camellia sinensis L.) clones: I. Measurement of water use in young tea using sap flow meters with a stem heat balance method

Sap flow meters based on the stem heat balance method were used to measure the mass flow rates or water use in young potted tea (Camellia sinensis L.) plants of clones AHP S15/10 and BBK35. The meters were constructed on site and installed onto the stem or branch sections of field growing plants in an experiment originally designed to study the effects of plant population density and drought on the productivity and water use of young tea clones. The objective of the study was to use the SHB method as a first attempt to use sap flow meters for determining the water use of young tea growing in the field under well watered conditions in Tanzania. The results are reported and recommendation made for further work on using the technique.     

Sap flow in ‘Hass’ avocado trees on two clonal rootstocks in relation to xylem anatomy

The rates of sap flow and xylem vessel features were studied in two-year-old nongrafted and grafted avocado (Persea americana Mill.) trees. Daily sap flow rates were measured with heat and balance stem gauges in clonal Duke 7 (D7) and Toro Canyon (TC) trees and ‘Hass’ clonal scions grafted onto clonal D7 (H/D7) and TC (H/TC) rootstocks. Vessel features as size, number and total vessel area were determined histologically in the stem of the scion and rootstock and the roots of the grafted trees. Significant differences in the sap flow rate were found among the rootstocks, where D7 had a 29% higher sap flow rate than did TC (grafted and nongrafted trees). There were no differences among xylem vessel features in the stems of any of the varieties. However in the roots, D7 had wider and fewer vessels then TC do. Also, D7 had a 19% higher total vessel area than TC. These results suggest that the differences in water consumption of ‘Hass’ on different rootstocks may be associated with differences in the efficiency of the roots to absorb water across conductive tissue which may be linked to differences in the area of xylem vessels in the root.     

Determining reference values for stem water potential and maximum daily trunk shrinkage in young apple trees based on plant responses to water deficit

The use of plant water status indicators such as midday stem water potential (Ψ_stem) and maximum daily trunk shrinkage (MDS) in irrigation scheduling requires the definition of a reference or threshold value, beyond which irrigation is necessary. These reference values are generally obtained by comparing the seasonal variation of plant water status with the environmental conditions under non-limiting soil water availability. In the present study an alternative approach is presented based on the plant’s response to water deficit. A drought experiment was carried out on two apple cultivars (Malus domestica Borkh. ‘Mutsu’ and ‘Cox Orange’) in which both indicators (Ψ_stem and MDS) were related to several plant physiological responses. Sap flow rates, maximum net photosynthesis rates and daily radial stem growth (DRSG) (derived from continuous stem diameter variation measurements) were considered in the assessment of the approach. Depending on the chosen plant response in relationship with Ψ_stem or MDS, the obtained reference values varied between −1.04 and −1.46 MPa for Ψ_stem and between 0.17 and 0.28 mm for MDS. In both cultivars, the approach based on maximum photosynthesis rates resulted in less negative Ψ_stem values and smaller MDS values, compared to the approaches with sap flow and daily radial stem growth. In the well-irrigated apple trees, day-to-day variations in midday Ψ_stem and MDS were related to the evaporative demand. These variations were more substantial for MDS than for midday Ψ_stem.     

花期干旱胁迫后限源疏库对玉米光合性能和茎流的影响

开展玉米花期干旱限源疏库试验,探索减轻花期干旱胁迫的技术途径。结果表明,去根叶组叶片可显著减少植株前期茎流,抑制叶片蒸腾,对穗5叶的叶绿素相对含量、光系统Ⅱ最大光化学效率(Fv/Fm)和潜在活性(Fv/Fo)影响不显著,正常灌溉情况下还有利于延缓玉米花后穗5叶的衰老,并促进后期茎流超补偿;去耕作层1/4根系会加剧前期植株水分的散失,干旱时浅中耕的措施是不可取的,并抑制后期茎流,增大Fv/Fm;去穗虽然可以显著减少茎流,抑制叶片蒸腾,但是因缺少库需求而加速花后穗5叶的叶绿素相对含量、Fv/Fm和Fv/Fo下降,促使叶片衰老。品种间对花期干旱胁迫后不同的限源疏库处理表现出显著差异,这是生物节水和作物补偿生长的生理基础。     

Seasonal variation in canopy reflectance and its application to determine the water status and water use by citrus trees in the Western Cape, South Africa

This study describes the diurnal and seasonal dynamics of the canopy reflectance, water use and water status of Midknight Valencia citrus trees under semi-arid conditions. Hyperspectral canopy reflectance data was collected on 30 trees at monthly intervals over a period of 16 months in a commercial orchard in South Africa. The mean canopy reflectance in the wavelength range 350-2500 nm followed a clear seasonal trend influenced by environmental conditions and tree phenology. Mean monthly reflectance peaked in summer (∼22%) while the lowest value (∼15%) was reached in winter with the seasonal changes in the sun's position accounting for a significant proportion of the variations. A sensitivity analysis of a Penman-Monteith transpiration model showed that water use by individual trees changed by up to 13% when the canopy reflectance was varied over the seasonal range of measured values. This suggested that the seasonal changes in tree water use influenced the seasonal trend of the canopy reflectance. Thus monitoring the canopy reflectance of citrus trees could offer information on the tree water status. To test this, sap flow data of water uptake and loss by the trees were compared with the canopy spectra. Sap flow data showed a heavy reliance by the citrus trees on the internally stored water with up to 25% of the daily total transpiration withdrawn from the trees’ internal water storage pools when soil water was limited. This depletion of internally stored water, and hence the change in tree water status, was detected using spectral indices based on the first order derivatives of the canopy reflectance centered at two and, at most, four spectral bands. We conclude that even if citrus trees are evergreen, their canopy reflectance changes significantly throughout the year with a considerable impact on tree energy balance and water use. In addition, the contribution of the internally stored water to daily transpiration is a possible indicator of drought stress for citrus trees detectable from changes in canopy reflectance and it has potential applications in irrigation scheduling using canopy level spectral information.     

Water balance, transpiration and canopy conductance in two beech stands

Measurements of sap flow, vapour fluxes, throughfall and soil water content were conducted for 19 months in a young beech stand growing at low elevation, in the Hesse forest. This experiment is part of the Euroflux network, covering 15 representative European forests. Study of the radial variation of sap flow within tree trunks, showed a general pattern of sap flux density in relation to the depth below cambium. Among-tree variation of sap flow was also assessed, in order to determine the contribution of the different crown classes to the total stand transpiration. Stand sap flow and vapour flux, measured with eddy covariance technique, were well correlated, for half hourly as well for daily values, the ratios of the fluxes for both averaging periods being 0.77. A strong canopy coupling to the atmosphere was found, omega factor ranging between 0.05 and 0.20 relative to the windspeed. Canopy conductance variation was related to a range of environmental variables: global radiation, vapour pressure deficit, air temperature and soil water deficit. In addition to the effect of radiation and of vapour pressure deficit often found in various other tree species, here beech exhibited a strong reduction in canopy conductance when air temperature decreased below 17°C. The model of transpiration was calibrated using data measured in the Hesse forest and applied to another beech stand under mountainous conditions in the Vosges mountains (east France). Measured and modelled stand transpiration were in good agreement.     

山西太岳山辽东栎夏季树干液流通量研究

树干液流指蒸腾在植物体内引起的上升液流。土壤液态水进入根系后 ,由茎输导组织向上运送达冠层 ,经由气孔蒸腾 (包括角质层及皮孔蒸腾 )转化为气态水扩散到大气中去。根部吸收的水分有 99 8%以上消耗在蒸腾上 (王沙生等 ,1 991 )。通过精确测算茎流量 ,可以基本确定植株蒸腾失     

生长季白桦树干液流密度的特征

应用热扩散技术测定了帽儿山不同径级白桦样木生长季的树干液流,并初步分析和对比了优势木、中等木和被压木树干液流密度的特征及季节变化趋势。结果表明,白桦树干液流密度变化具有明显的昼夜节律性,一般呈单峰曲线;白桦优势木液流密度明显大于中等木和被压木,中等木和被压木液流密度值非常接近;不同天气条件下液流密度日变化规律大不相同,阴雨天液流密度值较小且变化曲线十分不规则,波动性较大,甚至出现多峰曲线。生长季,优势木、中等木和被压木日液流通量最大值均出现在6月初至7月中旬,分别为2623.97、1744.50、1689.82L.m-2.d-1;优势木日液流通量最小值出现在7月下旬至8月初,中等木和被压木日液流通量最小值均出现在生长季末期。随季节的推移,生长季各月份液流密度均值基本逐渐减小,白桦优势木6、7月份液流密度平均值较大,8月份和9月份液流密度均值较接近,10月份明显减小;中等木液流密度平均值7月份最大,6、8、9月份液流密度均值较接近,10月份液流密度波动微弱;被压木最大值出现在6月份,7、8、9月份液流密度月均值变化不大。     

Sap flow in papaya plants: Laboratory calibrations and relationships with gas exchanges under field conditions

In papaya plants a study to quantify the water flow through the trunk is important for to promote a good water management in commercial orchard. The objective was to study the relationship between water flow through the trunk and temperature measurements determined by probes inserted in the papaya plant stem in laboratory. In addition, was possible to study the relationship between sap flow and instantaneous gas exchange in field conditions. We constructed an instrument that maintained a stable water flux through a 0.30 m stem section with a constant pressure, simulating the xylem sap flow through the stem. Water flux was adjusted by varying pressure of water in the stem section. The mathematical model used to fit the relation between K (Granier heat coefficient) values and sap flow density was the exponential model: u = 0.5511 × K^1.9104. Field studies was conducted in a commercial orchard located in North of the State of Rio de Janeiro, with 12 plants in October 2002, and eight plants in January 2003. We verified that instantaneous transpiration, measured by a portable system of gas exchange (porometry), presented a good (R² = 0.75) positive relationship with xylem sap flow. Estimates of papaya sap flow can be obtained by scaling portable photosynthesis system measurements with exposed leaves, however the relationship is non-linear in higher instantaneous transpiration rates. The causes of the non-linear relationship in higher transpiration are discussed. In addition, was possible to obtain a good (R² = 0.76) relationship between net photosynthesis rate and xylem sap flow in papaya field-grown.