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Research and Technology Transfer of the Application Use of Sap Flow Sensors to Improve Fruit Production

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Abstract

The measurement of sapflow in the stem of fruit trees by heat-pulse method, it is necessary to investigate the parameters of sapwood. In this research, 4 species of tropical fruits (durian, mangoteen, rambutan and longkong) were conducted. It was found that wood density or wood fraction volume of durian was lowest (VW = 0.30), followed by those of longkong (VW = 0.43) and rambutan (VW = 0.45) While word density of mangoteen was the highest (VW = 0.52). The other parameters: stem diameter, sap-wood range and bark thicken were also determined. All parameters were used in calculation of sapflow rates in the fruit trees. Then, the heat-pulse sapflow sensors (PSU-NRC) were used to measure water use of the tested plants (3-year longkong tree grown in the plot) compared with the measurement by gravimetric method. There was high correlation (r2 = 0.91) between the both methods. This indicated the reliable of the measurement by heat-pulse sapflow sensor (PSU-NRC).

The measurement in the field-trial was done at the Department of Plant Science, Faculty of Natural Resource. Continuous measurement was tested in rambutan and longkong. It was found that the equipment can be uses for the continuously automated record. However, there was a problem of broken probe when it was installed on the tree for a long period. Therefore, the probe was improved to be stronger. Beside, it was found that the result of measurement in durian was not consistency. While the measurement in the other species were consistency. The, anatomical study of sapwood in the 4 species of the fruit trees was done by Scanning Electron Microscope (SEM), permanent slide to determine xylem vessels diameter and distance between xylem vessel. The result showed that xylem vessel in the sapwood of durian was quite heterogeneous, but xylem vessel in the sapwood of remaining species were homogeneous. This indicated that reliability of heat-pulse method depended on homogeneous of xylem vessel in the sap-wood. Hence, it is suggested that heterogeneous of xylem vessel in the sap-wood is a limiting factor in the sapflow measurement using heat-pulse method.

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Fl = (Wf � Wd) / Wi Fm = Wd / (1.53 x Wi)

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y = 0.94x

r2 = 0.91** (n = 38)

0.00 0.20 0.40 0.60 0.80 1.00 1.20 1.40 1.60

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Average P

(µmol m

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Sapflow

(l/hr)

Temperature (o C

0510152025303540

18 19 20 21 23 22 17

12.00 12.00 00.00 00.00 00.00 00.00 00.00 00.00 00.00 00.00 12.00 12.00 12.00 12.00 12.00

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12.00 12.00 00.00 00.00 00.00 00.00 00.00 00.00 00.00 00.00 12.00 12.00 12.00 12.00 12.00

4 5 6 7 9 8 3 ��/�+� 2550

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1 3 5 7 9 11 13 15 17 19 21 23

Durian Mangoteen Rambutan Longkong

1 3 5 7 9 11 13 15 17 19 21 23

�� 1

�� 2

Leaf water po

tential (MPa)

7 9 11 13 15 17

7 9 11 13

7 9 11 13 15

atal conductance (cm

Sap flow rates (l/hr)

�%�� 18 �� !��%��)� (A), ��* (B), ��$ (C) �#$#�� (D) C!) �*=�)�#=��

�#%�� #Q�&��!��* (1.x40., 2.x450.)

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(B), ��$ (C) �#$#�� (D)

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Diameter of xylem vessels (µm) 150-350 30-80 70-120 70-150 Spacing between xylem vessels (µm) 25-1500 50-500 50-350 25-350

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�;�� >?��>&� 2541 "#��$%��0��#��1�&!� ��>&��!�� >?��>&� �,%�� 44 �#!�%�� 499 ��C��)� 2541 <�= 13-14

Caspari, H.W., Behboudian, M.H, Chalmers, D.J. and Renquist, A.R. 1993. Pattern of seasonal water use of Asian pears determined by lysimeters and the heat-pulse technique. J. Amer. Soc. Hort.Sci. 118(5): 562-569.

Cohen, Y., Fuchs, M. and Green, G.C. 1981. Improvement of heat pulse method for determining sap flow in trees. Plant, Cell and Environment 4: 391-397.

Edwards, W.R.N. and Warwick, N.W.M. 1984. Transpiration from a kiwifruit vine as estimated by the heat pulse technique and the Penman Monteith equation. N.Z.J. Agr. Res. 27: 537-543.

Elfving, D.C. 1982. Crop response to trickle irrigation. Hort. Rev. 4: 1-48. Fernandez, J.E., Duran, P.J., Palomo, M.J., Diaz-Espejo, A., Chamorro, V. and Diron, I.F. 2006.

Calibration of sap flow estimated by the compensation heat pulse method in olive, plum and orange trees : relationships with xylem anatomy. Tree Physiol. 26:719-28.

Granier, A., Bobay, V., Gash, J.H.C., Gelpe, J., Sangier, B. and Shuttleworth, W.J. 1990. Vapour flux density and transpiration rate comparisons in a stand of maritime pine (Pinus pinasta Ait) in Les Landes forest. Agic. For. Meteorol. 51: 309-319.

Green, S.R. and Clothier, B.E. 1988. Water use of kiwifruit vines and apple trees by the heat pulse technique. J. of Exp. Bot. 39: 115-123.

Green, S.R and Clothier, B.E. 1995. Root water uptake by kiwifruit vines following partial wetting of the root zone. Plant and Soil 17: 317-328.

Green, S.R., Clothier, B.E. and Mcleod, D.J. 1997. The response of sap flow in apple roots to localized irrigation. Agric. Water Manage. 33: 63-78.

Lonquenesse, J.J., C. Lenardi, K.E. Cockshull, Y. Tuzel and A. Gul. 1994. Some ecoohysiological indicators of salt stress in greenhouse tomato plants. Acta Horticulturae 336: 461-467.

Moreno, F., Fernandez, J.E., Clothier, B.E and Green, S.R. 1996. Transpiration and root water uptake by olive trees. Plant and Soil 184: 85-96.

Schuch, U.K. and Burger, D.W. 1997. Water use and crop coefficient of woody ornamentals in containers. J. Amer. Soc. Hort. Sci. 122(5): 727-734.

Smith, D.M and Allen, S.J. 1996. Measurement of sap flow in plant stems. J.Exp.Botany. 47(305):1833-1844.

Steinberg. S.L., McFarland, M.F. and Worthington, J.W. 1990. Comparison of trunk and branch sap flow with canopy transpiration in pecan. J. Exp. Botany 41: 653-659.

Vieweg, G.I.I. and Zigler, I.I. 1960. Thermoelektrische Registriezing der Geschwindigkeit des transpirationsstromes. Berichte Dentsche Botanische Gesellschaft 73: 221-226.

M #, %#J ! ˆ , N #! (ˆ ) ˆ ˆ˛)!(˝(Oˇ ˜P 2551 · durian was lowest (VW = 0.30 ), followed by...

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