Wind profiles in and over trees

Zhu Jiao-jun , LI Xiu-fen , Gonda Yutaka , Matsuzaki Takeshi

Journal of Forestry Research ›› 2004, Vol. 15 ›› Issue (4) : 305 -312.

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Journal of Forestry Research ›› 2004, Vol. 15 ›› Issue (4) : 305 -312. DOI: 10.1007/BF02844959
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Wind profiles in and over trees

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Abstract

One of the most important and frequently studied variable in forests and the most basic element in governing transport processes of airflow is wind speed. The study of wind profile, defined as the change of wind velocity with height, and wind velocity are important because of tree physiological and developmental responses. Generally, wind profiles above the ground or at a canopy surface follow classical logarithm law, but wind profiles in a single tree and in a forest stand are not logarithmic. This paper summarizes the results of wind profile studies within a single tree, in a forest stand, above the forest canopy and in a forest area from recent research in a coastal pine forest. The results demonstrate that: 1) wind profiles with in a single conifer tree crown showed an exponential function with height, 2) wind profiles in forest stands were able to be expressed by attenuation coefficient of wind, 3) wind profiles over a forest canopy could be determined using profile parameters (friction velocity, roughness length and displacement), and 4) for a forest area, the extreme wind speed could be predicted reasonably using the methods developed for the design of buildings. More research will be required to demonstrate: 1) relationships between wind profiles and tree or stand characteristics, 2) the simple methods for predicting wind profile parameters, and 3) the applications of wind profile in studies of tree physiology, forest ecology and management, and the detail ecological effects of wind on tree growth.

Keywords

Wind / Wind profile / Trees / Forest ecology

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Zhu Jiao-jun, LI Xiu-fen, Gonda Yutaka, Matsuzaki Takeshi. Wind profiles in and over trees. Journal of Forestry Research, 2004, 15(4): 305-312 DOI:10.1007/BF02844959

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Abtew W., Gregory J.M., Borrelli J. Wind profile: Estimation of displacement height and aerodynamic roughness [J]. Transactions of the ASAE, 1989, 32: 521-527.
[2]

Allen L.H. Turbulence and windspeed spectra within a Japanese larch plantation [J]. Journal of Applied Meteorology, 1968, 7: 73-78.

[3]

Aloysius K. Determination of zero-plane displacement and roughness length of a forest crown using profiles of limited height [J]. Boundary-Layer Meteorology, 1995, 75: 381-402.

[4]

Amiro B.D. Comparison of turbulence statistics within three boreal forest canopies [J]. Boundary-Layer Meteorology, 1990, 51: 99-121.

[5]

Amiro B.D. Drag coefficients and turbulence spectra within three boreal forest canopies [J]. Boundary-Layer Meteorology, 1990, 52: 227-246.

[6]

Asai T. Local meteorology [M], 1996 Tokyo: University of Tokyo Press
[7]

Bergen J.D. Vertical profiles of windspeed in a pine stand [J]. Forest Science, 1971, 17: 314-321.
[8]

Blackburn P., Petty J.A. Theoretical calculations of the influence of spacing on stand stability [J]. Forestry, 1988, 61: 235-244.

[9]

Bull, G.A.D. and Reynolds, E.R.C. 1968. Wind turbulence generated by vegetation and its application [J]. Forestry Supplement, 28–37.
[10]

Cao Xinsun Shelterbelt for Farmland [M], 1983 Beijing: Chinese Forestry Press
[11]

Cheng E.D.H., Chiu A.N.L. Extreme winds simulated from short-period records [J]. Journal of Structural Engineering, 1985, 111: 77-94.

[12]

Cionco R.M. Hutchison B. A., Hicks B. B. Modeling windfields and surface wind profiles over complex terrain and within vegetation canopies [C] The forest-atmosphere interaction, 1985 Dordrecht, Boston, Lancaster: D. Reidel publishing company 501-520.
[13]

Coutts M.P., Grace J. Coutts M. P., Grace J. Preface [C] Wind and trees, 1995 Cambridge: Cambridge University Press 9-10.
[14]

Dyrbye C., Hansen S.O. Wind Loads on Structures [M], 1997 Chichester, England: John Wiley and Son Ltd.
[15]

Galambos J., Macri N. Classical extreme value model and prediction of extreme winds [J]. Journal of Structural Engineering, 1999, 125: 792-794.

[16]

Gardiner B.A. Wind and wind force in a plantation spruce forest [J]. Boundary-Layer Meteorology, 1994, 67: 161-186.

[17]

Gardiner B.A. Coutts M. P., Grace J. The interaction of wind and tree movement in forest canopies [C] Wind and trees, 1995 Cambridge: Cambridge University Press 41-59.
[18]

Gardiner B.A., Stacy G.R., Belcher R.E., Wood C.J. Field and wind tunnel assessments of the implications of respacing and thinning for tree stability [J]. Forestry, 1997, 70: 233-252.

[19]

Grigoriu M. Estimates of extreme winds from short records [J]. Journal of Structural Engineering, 1984, 110: 1467-1484.
[20]

Gross J., Heckert A., Slcchner J., Simiu E. Galambos J. Novel extreme value estimation procedures: Application to extreme wind data [C] Extreme value theory and applications, 1994 Netherlands: Kluwer Academic Publishers 139-158.
[21]

Gusella V. Estimation of extreme winds from short-term records [J]. Journal of Structural Engineering, 1991, 117: 375-390.

[22]

Hannah P., Palutikof J.P., Quine C.P. Coutts M. P., Grace J. Predicting windspeeds for forest areas in complex terrain [C] Wind and trees, 1995 Cambridge: Cambridge University Press 113-132.
[23]

Ishizaki K., Ota M. Wind profiles above a forest canopy [J]. Research Bulletin of the Hokkaido University Forest, 1987, 44: 416-475.
[24]

Kaimal J.C., Finnigan J.J. Atmospheric Boundary Layer Flows: Their Structure and Measurement [M], 1994 Harbin — USA: Oxford University Press
[25]

Kimmins, J.P. 1987. Forest Ecology [M]. New York, Macmillan, London, Collier Macmillan, 531 pp.
[26]

Kondo J., Akashi S. Numerical studies on the two-dimensional flow in horizontal homogeneous canopy layers [J]. Boundary-Layer Meteorology, 1976, 10: 255-272.

[27]

Kotoda K., Hayashi Y. On the wind profile above plant canopies and its aerodynamic properties [J]. Journal of Agricultural Meteorology, Japan, 1980, 35: 221-228.
[28]

Kuraji K., Tanaka N., Shiraki K., Karakama I., Ohta T. Effects of windspeed on stem-flow volume in a matureCryptomeria japonica andChamaecyparis obtusa stand [J]. Journal of Forest Research, Japan Forestry Society, 1997, 79: 215-221.
[29]

Landsberg J.J., James G.B. Wind profiles in plant canopies: studies on an analytical model Journal of Applied Ecology, 1971, 8: 729-741.

[30]

Lemone M.A., Zhou M. Y., Money C.H., Lenschow D.H., Mille L. J., Grossman R.L. An observational study of wind profiles in the barochinic convective mixed layer [J]. Boundary-Layer Meteorology, 1998, 90: 47-82.

[31]

Liu J.M., Kotoda K. Evaluation of surface-layer wind profiles with HEIFE observations [J]. Boundary-Layer Meteorology, 1996, 83: 27-41.

[32]

Lyles L., Allison B.E. Wind profile parameters and turbulence intensity over several roughness element geometries [J]. Transactions of the ASAE, 1979, 22: 334-343.
[33]

Maki T. Wind and nature [M], 1999 Tokyo: Kaihutsushia Press
[34]

Miller J.F. Plate E. Precipitation evaluation in hydrology [C] Engineering meteorology Studies in wind engineering and industrial aerodynamics 1, 1982 Amsterdam, Oxford, New York: Elsevier, Scientific Publishing Company 371-424.
[35]

Milne R. Extreme wind speeds over a Sitka spruce plantation in Scotland Agricultural and Forest Meteorology, 1992, 61: 39-53.

[36]

Munn R.E. Descriptive Micrometeorology [M], 1966 Harbin, San Fransisco, London: Academic press
[37]

Murai H., Ishikawa M., Endo J., Tadaki R. The Coastal Forests in Japan [M], 1992 Tokyo: Soft Science, INC.
[38]

Oliver H.R. Wind profiles in and above a forest canopy [J]. Quarterly Journal Royal Meteorological Society, 1971, 97: 548-553.

[39]

Oliver H.R., Mayhead G.J. Wind measurements in a pine forest during a destructive gale [J]. Forestry, 1974, 47: 185-195.

[40]

Oliver H.R. Wind speeds within the trunk space of a pine forest [J]. Quarterly Journal Royal Meteorological Society, 1975, 101: 167-168.

[41]

Peltola H. Model computations on wind flow and turning moment by wind for Scots pines along the margins of clear-cut areas [J]. Forest Ecology and Management, 1996, 83: 203-215.

[42]

Peltola H., Kellomaki S., Kolstrom T., Lassig R., Moor J., Quine C., Ruel J.C. Wind and other abiotic risks to forests [J]. Forest Ecology and Management, 2000, 135: 1-2.

[43]

Plate E.J. The aerodynamics of shelterbelts [J]. Agricultural Meteorology, 1971, 8: 203-222.

[44]

Quine C.P. Estimation of mean wind climate and probability of strong winds for wind risk assessment [J]. Forestry, 2000, 73: 247-258.

[45]

Raynor G. Wind and temperature structure in a coniferous forest and a contiguous field [J]. Forest Science, 1971, 17: 351-363.
[46]

Reifsnyder W.E. Wind profiles in a small isolated forest stand [J]. Forest Science, 1955, 1: 189-297.
[47]

Simiu E., Filliben J.J. Weibull distributions and extreme wind speeds [J]. Journal of Structural Division, 1980, 106: 2365-2374.
[48]

Simiu E., Filliben J.J. Short term records and extreme wind speeds [J]. Journal of Structural Division, 1982, 108: 2571-2577.
[49]

Simiu E., Hendrickson E.M., Nolan W.A., Olkin I. Multivariate distributions of directional wind speeds [J]. Journal of Structural Division, 1985, 111: 939-943.

[50]

Simiu E., Heckert N.A. Extreme wind distribution tails: a “peaks over threshold” approach [J]. Journal of Structural Engineering, 1996, 122: 539-547.

[51]

Taketa K. Turbulence in plant canopies [J]. Journal of Agricultural Meteorology, Japan, 1964, 20: 1-5.
[52]

Taketa K. Turbulence in plant canopies (2) [J]. Journal of Agricultural Meteorology, Japan, 1965, 21: 11-14.
[53]

Telewski F.W. Coutts M. P., Grace J. Wind-induced physiological and developmental responses in trees [C] Wind and trees, 1995 Cambridge: Cambridge University Press 237-263.
[54]

Thorn A.S. Momentum absorption by vegetation [J]. Quarterly Journal Royal Meteorological Society, 1971, 97: 414-428.

[55]

Thorn A.S. Momentum, mass and heat exchange of vegetation [J]. Quarterly Journal Royal Meteorological Society, 1972, 98: 124-134.

[56]

Xie Dingyu Fluid mechanics [M], 1987 Tianjin: Press of Nankai University
[57]

Zhu J.J., Matsuzaki T., Sakioka K., Yamamoto M. Windspeed in a coastal forest belt of Japanese black pine (Pinus thunbergii Parl.): Vertical wind profile [J]. Transactions of the Japanese Forestry Society, 1998, 109: 455-458.
[58]

Zhu J.J., Matsuzaki T., Sakioka K. Windspeeds within a single crown of Japanese black pine (Pinus thunbergii Parl.) [J]. Forest Ecology and Management, 2000, 135: 19-31.

[59]

Zhu J.J., Matsuzaki T., Gonda Y. Wind profiles in a coastal forest of Japanese black pine (Pinus thunbergii Parl.) with different thinning intensities [J]. Journal of Forest Research, the Japanese Forestry Society, 2001, 6: 287-296.
[60]

Zhu J.J., Matsuzaki T., Gonda Y. Extreme wind over a pine coastal forest plantation at Aoyama of Niigata in Japan [J]. Journal of the Japan Society of Erosion Control Engineering, 2001, 54: 12-20.
[61]

Zhu J.J., Matsuzaki T., Jiang F.Q. Wind on Tree Windbreaks [M], 2004 Beijing: China Forestry Publishing House
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