ESTIMATION OF TRANSPIRATION IN COMMUNITIES DOMINATED BY SHRUB CARAGANA MICROPHYLLA

doi:10.3773/j.issn.1005-264x.2009.03.010

Abstract

Abstract:

Aims Our objectives were to develop an appropriate procedure for scaling up the sap flow from individual stems to the whole shrub and to the plot and to assess the utility of using sap flow gauges to determine the stand-level transpiration of shrub plantations in a semiarid sandy environment.

Methods Sap flow rates of stems in a 15-year-old Caragana microphylla shrub in Horqin Sandy Land, China were measured using the stem heat balance techniques in June 2006 to determine transpiration of the C. microphylla plantation. The gauge-equipped stems, ranging in basal diameter from 0.4 to 1 cm, were selected on the basis of statistical analysis within the representative sampling plot for determining the “mean stem”. Synchronously, total leaf area of the plant was measured by the basal cross-sectional area method and the leaf area density (LAD) method. We took advantage of the sparse distribution of C. microphylla and the ease of directly measuring LAD for individual shrubs to create a new scaling method based on these direct LAD measurements for shrubs in the study plot. We extrapolated the measurements of water use by individual stems to determine the area-averaged transpiration of the shrubland. The method used for the extrapolation assumed that the transpiration of a shrub was proportional to its leaf area.

Important findings We found daily differences of <14.3% between transpiration estimated with sap measurements and with a weighing lysimeter reference, suggesting that the scaling procedure can be used to provide reliable estimates of transpiration from the shrub C. microphylla in Horqin Sandy Land.

Key words: heat balance techniques, Caragana microphylla, individual stem transpiration, leaf area, scaling-up, community transpiration

YUE Guang-Yang, ZHAO Ha-Lin, ZHANG Tong-Hui, ZHAO Xue-Yong, ZHAO Wei, NIU Li, LIU Xin-Ping. ESTIMATION OF TRANSPIRATION IN COMMUNITIES DOMINATED BY SHRUB CARAGANA MICROPHYLLA[J]. Chin J Plant Ecol, 2009, 33(3): 508-515.

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URL: https://www.plant-ecology.com/EN/10.3773/j.issn.1005-264x.2009.03.010

https://www.plant-ecology.com/EN/Y2009/V33/I3/508

Figures/Tables 6

Fig.1 Frequency distribution in different basal diameter classes of Caragana microphylla

Table 1 Parameters for the equation relation leaf area (cm2) to stem cross-sectional area (cm2) for Caragana microphylla A-F

Fig. 2 The relationship between basal cross-sectional area and leaf area per stem for Caragana microphylla A-F The parameters of the regression lines are given in Table 1

Fig. 3 Comparison of estimated leaf area values between basal cross-sectional area method (A1) and leaf area density method (A2) Acs: Total basal cross-sectional area

Fig. 4 Diurnal water consumption of Caragana microphylla determined by scaling sap flow rates of sampled individual stems in June 2006 No data were recorded on some days, because of power failure and gauges remove T: Diurnal water consumption

Fig.5 Comparison between shrub transpiration values determined by the stem heat-balance method and those (El) calculated by the weighed lysimeter method throughout June 2005 See Fig.4

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