Chinese Journal of Applied Ecology ›› 2017, Vol. 28 ›› Issue (8): 2438-2444.doi: 10.13287/j.1001-9332.201708.035
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DU Meng-ge1, WANG Sheng2, FANG Jun1,2*
Received:
2017-04-18
Published:
2017-08-18
Contact:
* E-mail: fanjun@ms.iswc.ac.cn
Supported by:
DU Meng-ge, WANG Sheng, FANG Jun. Application of the penta-needle heat pulse probes to determine the stem sap flow[J]. Chinese Journal of Applied Ecology, 2017, 28(8): 2438-2444.
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URL: https://www.cjae.net/EN/10.13287/j.1001-9332.201708.035
[1] Wang H-T (王华田), Ma L-Y (马履一). Measurement of whole tree water consumption with thermal dissipation sap flow probe (TDP). Acta Phytoecologica Sinica (植物生态学报), 2002, 22(6): 661-667 (in Chinese) [2] Kramer PJ, Boyer JS. Water Relations of Plants and Soils. London: Academic Press, 1995 [3] Kramer PJ. Sap pressure and exudation. American Journal of Botany, 1940, 27: 929-931 [4] Canny MJ. Flow and transport in plants. Annual Review of Fluid Mechanics, 1977, 9: 275-296 [5] Heine RW, Farr DJ. Comparison of heat-pulse and radioisotope tracer methods for determining sap-flow velocity in stem segments of poplar. Journal of Experimental Bo-tany, 1973, 24: 649-654 [6] Granier A. A new method of sap flow measurement in tree stems. Annals of Forest Science, 1985, 42: 193-200 [7] Trcala M, Cˇermák J. A new heat balance equation for sap flow calculation during continuous linear heating in tree sapwood. Applied Thermal Engineering, 2016, 102: 532-538 [8] Kuroda K, Kanbara Y, Inoue T, et al. Magnetic resonance micro-imaging of xylem sap distribution and necrotic lesions in tree stems. IAWA Journal, 2006, 27: 3-17 [9] Huber B. Observation and measurements of sap flow in plant. Reports of German Botanical Society, 1932, 50: 89-109 [10] Marshall DC. Measurement of sap flow in conifers by heat transport. Plant Physiology, 1958, 33: 385-396 [11] Swanson RH, Whifield DWA. A numerical analysis of heat pulse velocity theory and practice. Journal of Expe-rimental Botany, 1981, 32: 221-239 [12] Edwards WRN, Jarvis PG. A method for measuring radial differences in water content of intact tree stems by attenuation of gamma radiation. Plant, Cell and Environment, 1983, 6: 255-260 [13] Burgess SS, Adams MA, Turner NC, et al. An improved heat pulse method to measure low and reverse rates of sap flow in woody plants. Tree Physiology, 2001, 21: 589-598 [14] Cohen Y, Fuchs M, Green GC. Improvement of the heat pulse method for determining sap flow in trees. Plant, Cell and Environment, 1981, 4: 391-397 [15] Masmoudi MM, Mahjoub I, Lhomme JP, et al. Sap flow measurement by a single thermal dissipation probe: Exploring the transient regime. Annals of Forest Science, 2009, 66: 1-7 [16] Campbell GS, Calissendorff C, Williams JH. Probe for measuring soil specific heat using a heat-pulse method. Soil Science Society of America Journal, 1991, 55: 291-293 [17] Basinger JM, Kluitenberg GJ, Ham JM, et al. Laboratory evaluation of the dual-probe heat-pulse method for measuring soil water content. Vadose Zone Journal, 2003, 2: 389-399 [18] Ham JM, Benson EJ. On the construction and calibration of dual-probe heat capacity sensors. Soil Science Society of America Journal, 2004, 68: 1185-1190 [19] Kluitenberg GJ, Ochsner TE, Horton R. Improved analysis of heat pulse signals for soil water flux determination. Soil Science Society of America Journal, 2007, 71: 53-55 [20] Ochsner TE, Horton R, Kluitenberg GJ, et al. Evaluation of the heat pulse ratio method for measuring soil water flux. Soil Science Society of America Journal, 2005, 69: 757-765 [21] Vandegehuchte MW, Steppe K. A triple-probe heat-pulse method for measurement of thermal diffusivity in trees. Agricultural and Forest Meteorology, 2012, 160: 90-99 [22] Wang S (王 胜), Fan J (樊 军). Application of three heat pulse technique-based methods to determine the stem sap flow. Chinese Journal of Applied Ecology (应用生态学报), 2015, 26(8): 2244-2230 (in Chinese) [23] Yang C, Sakai M, Jones SB. Inverse method for simultaneous determination of soil water flux density and thermal properties with a Penta-needle heat pulse probe. Transport in Porous Media, 2010, 49: 5851-5864 [24] Yang C, Jones SB. INV-WATFLX, a code for simultaneous estimation of soil properties and planar vector water flux from fully or partly functioning needles of a Penta-needle heat-pulse probe. Computers & Geosciences, 2009, 35: 2250-2258 [25] Kluitenberg GJ, Kamai T, Vrugt JA, et al. Effect of probe deflection on dual-probe heat-pulse thermal conductivity measurements. Soil Science Society of America Journal, 2010, 74: 1537-1540 [26] Ballester C, Castel J, Testi L, et al. Can heat-pulse sap flow measurements be used as continuous water stress indicators of citrus trees? Irrigation Science, 2013, 31: 1053-1063 [27] Wang S, Fan J, Wang Q. Determining evapotranspiration of a Chinese willow stand with three-needle heat-pulse probes. Soil Science Society of America Journal, 2015, 79: 1545-1555 [28] Xiao X, Horton R, Sauer TJ, et al. Cumulative soil water evaporation as a function of depth and time. Vadose Zone Journal, 2011, 10: 1016-1022 [29] Kathy S, Dirkjw DP, Tanyam D, et al. A comparison of sap flux density using thermal dissipation, heat pulse velocity and heat field deformation methods. Agricultural and Forest Meteorology, 2010, 150: 1046-1056 [30] Shinohara Y, Tsuruta K, Ogura A, et al. Azimuthal and radial variations in sap flux density and effects on stand-scale transpiration estimates in a Japanese cedar forest. Tree Physiology, 2013, 33: 550-558 [31] Poyatos R, Cermák J, Llorens P. Variation in the radial patterns of sap flux density in pubescent oak (Quercuspubescens) and its implications for tree and stand transpiration measurements. Tree Physiology, 2007, 27: 537-548 [32] Ren R, Liu G, Wen M, et al. The effects of probe misa-lignment on sap flux density measurements and in situ, probe spacing correction methods. Agricultural and Forest Meteorology, 2017, 232: 176-185 [33] Knight JH, Kluitenberg GJ, Kamai T, et al. Semianalyti-cal solution for dual-probe heat-pulse applications that accounts for probe radius and heat capacity. Vadose Zone Journal, 2012, 11: 460 [34] Barker M, Becker P. Sap flow rate and sap nutrient content of a tropical rain forest canopy species, Dryobala-nops aromatica, in Brunei. Selbyana, 1995, 16: 201-211 [35] Fisher JB, Baldocchi DD, Misson L, et al. What the towers don't see at night: Nocturnal sap flow in trees and shrubs at two ameri flux sites in California. Tree Physiology, 2007, 27: 597-610 [36] Vandegehuchte M, Burgess SS, Downey A, et al. Stem temperature influence on heat pulse sap flux density measurements. Acta Horticulturae, 2013, 991: 85-92 [37] Herbst M, Rosier PT, Morecroft MD, et al. Comparative measurements of transpiration and canopy conduc-tance in two mixed deciduous woodlands differing in structure and species composition. Tree Physiology, 2008, 28: 959-970 [38] Liu H-J (刘海军), Cohen S, Tanny J, et al. Transpiration of banana plant measured by Granier method. Chinese Journal of Applied Ecology (应用生态学报), 2007, 18(1): 35-40 (in Chinese) [39] Do F, Rocheteau A. Influence of natural temperature gradients on measurements of xylem sap flow with thermal dissipation probes. 2. Advantages and calibration of a noncontinuous heating system. Tree Physiology, 2002, 22: 649-654 [40] Liu Q-X (刘庆新), Meng P (孟 平), Zhang J-S (张劲松), et al. Calibration coefficients of Granier original formula based on sap flow of Platycladus orientalis. Acta Ecologica Sinica (生态学报), 2013, 33(6): 1944-1951 (in Chinese) [41] Lu P, Urban L, Zhao P. Granier’s thermal dissipation probe (TDP) method for measuring sap flow in trees: Theory and practice. Acta Botanica Sinica, 2004, 46: 631-646 [42] Reyes-Acosta JL, Vandegehuchte MW, Steppe K, et al. Novel, cyclic heat dissipation method for the correction of natural temperature gradients in sap flow measurements, Part 2: Laboratory validation. Tree Physiology, 2012, 32: 913-929 |
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