Roughness length and zero-plane displacement over three typical surfaces were calculated iteratively by least-square method, which are Yucheng Experimental Station for agriculture surfaces, Qianyanzhou Experimental Station for complex and undulant surfaces, and Changbai Mountains Experimental Station for forest surfaces. On the basis of roughness length dynamic, the effects of roughness length dynamic on fluxes were analyzed with SEBS model. The results indicate that, aerodynamic roughness length changes with vegetation conditions (such as vegetation height, LAI), wind speed, friction velocity and some other factors. In Yucheng and Changbai Mountains Experimental Station, aerodynamic roughness length over the fetch of flux tower changes with vegetation height and LAI obviously, that is, with the increase of LAI, roughness length increases to the peak value firstly, and then decreases. In Qianyanzhou Experimental Station, LAI changes slightly, so the relationship between roughness length and LAI is not obvious. The aerodynamic roughness length of Yucheng and Changbai Mountains Experimental Station changes slightly with wind direction, while aerodynamic roughness length of Qianyanzhou Experimental Station changes obviously with wind direction. The reason for that is the terrain in Yucheng and Changbai Mountains Experimental Station is relatively flat, while in Qianyanzhou Experimental Station the terrain is very undulant and heterogeneous. With the increase of wind speed, aerodynamic roughness length of Yucheng Experimental Station changes slightly, while it decreases obviously in Qianyanzhou Experimental Station and Changbai Mountains Experimental Station. Roughness length dynamic takes great effects on fluxes calculation, and the effects are analyzed by SEBS model. By comparing 1 day averaged roughness length in Yucheng Experimental Station and 5 day averaged roughness length of Qianyanzhou and Changbai Mountains Experimental Station with roughness length parameter chosen by the model, the effects of roughness length dynamic on flux calculation is analyzed. The maximum effect of roughness length dynamic on sensible heat flux is 2.726%, 33.802% and 18.105%, in Yucheng, Qianyanzhou, and Changbai Mountains experimental stations, respectively.
[1]
Michiaki Sugita,et al.
Regional Roughness Parameters and Momentum Fluxes over a Complex Area
,
1996
.
[2]
Hans Peter Schmid,et al.
The influence of surface texture on the effective roughness length
,
1995
.
[3]
Michael R. Raupach,et al.
Simplified expressions for vegetation roughness length and zero-plane displacement as functions of canopy height and area index
,
1994
.
[4]
William P. Kustas,et al.
Local energy flux estimates for unstable conditions using variance data in semiarid rangelands
,
1994
.
[5]
R. Vogt,et al.
Evaporation from a pine forest - using the aerodynamic method and bowen ratio method
,
1990
.
[6]
Teodoro Georgiadis,et al.
Method for Estimation of Surface Roughness and Similarity Function of Wind Speed Vertical Profile
,
1998
.
[7]
R. Shaw,et al.
Aerodynamic roughness of a plant canopy: A numerical experiment
,
1982
.
[8]
Zhilin Zhu,et al.
The improvement and validation of the model for retrieving the effective roughness length on TM pixel scale
,
2005,
Proceedings. 2005 IEEE International Geoscience and Remote Sensing Symposium, 2005. IGARSS '05..
[9]
P. J. Mason,et al.
The formation of areally‐averaged roughness lengths
,
1988
.
[10]
Z. Su.
The Surface Energy Balance System (SEBS) for estimation of turbulent heat fluxes
,
2002
.
[11]
P. J. Mason,et al.
On the parameterization of drag over small-scale topography in neutrally-stratified boundary-layer flow
,
1989
.
[12]
Zhilin Zhu,et al.
The retrieval of two-dimensional distribution of the earth’s surface aerodynamic roughness using SAR image and TM thermal infrared image
,
2004
.