Characteristics of turbulence over the semi‐fixed desert area north of Xinjiang, China

As the largest fixed and semi‐fixed desert in China, the Gurbantünggüt Desert undergoes a long period of snow cover in the winter and the rapid growth of ephemeral plants in the spring, presenting obvious seasonal changes in the underlying desert surface type, which can lead to variation in the turb...

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Bibliographic Details
Published in:Earth surface processes and landforms 2021-09, Vol.46 (12), p.2365-2378
Main Authors: Mamtimin, Ali, Wang, Yu, Sayit, Hajigul, Yang, Xing Hua, Yang, Fan, Huo, Wen, Zhou, Chenglong, Jin, Lili
Format: Article
Language:English
Subjects:
Arid regions
Atmospheric conditions
Boundary layer turbulence
Boundary layers
Climate change
Desertification
Deserts
Eddy covariance
Gurbantünggüt Desert
Night
Seasonal variation
Seasonal variations
Snow cover
Spring
Spring (season)
Surface boundary layer
Turbulence
turbulence characteristics
Turbulence intensities
turbulence intensity
turbulent kinetic energy
turbulent regimes
Wind
Wind speed
Wind velocities
Winter
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Summary:As the largest fixed and semi‐fixed desert in China, the Gurbantünggüt Desert undergoes a long period of snow cover in the winter and the rapid growth of ephemeral plants in the spring, presenting obvious seasonal changes in the underlying desert surface type, which can lead to variation in the turbulence of the near‐surface boundary layer turbulence over the desert. In this study, gradient tower data and eddy covariance data from 2017 were analysed to investigate the turbulence characteristics of the different surface boundary layers in the hinterland of the Gurbantünggüt Desert. The results indicate that stable atmospheric conditions in the desert occur exclusively during the early morning and at night in the desert, and the onset and duration of this stable state varies seasonally. Two regimes of intermittent turbulence occur during the night, a weak turbulent regime that occurs when the wind speed is less than the threshold and a strong turbulent regime when the wind speed exceeds the threshold, and different wind speed thresholds were observed at each level. These parameters follow a seasonal pattern of summer (July) > spring (April) > autumn (October) > winter (January) in terms of magnitude. The mean turbulence intensities of the along‐wind, cross‐wind and vertical wind are 0.5, 0.47 and 0.14, respectively, with Iu > Iv > Iw. The normalized standard deviation of the wind velocity components (σu, σv and σw) generally satisfies a 1/3 power‐law relation. Our results show that the night‐time turbulence regime classification for the Gurbantünggüt Desert strongly depends on meteorological and orographic features, and the intermittent turbulent events have the non‐stationarity of the flow in common. The results can contribute to the study of land surface processes, climate change and desertification in inland arid desert areas. Relationships between the turbulence intensity and wind velocity of the Gurbantünggüt Desert. (a) turbulent intensity of along‐wind, (b) turbulent intensity of cross‐wind, (c) turbulent intensity of vertical turbulent wind. (c) Diurnal variation of the stability parameter (z/L) under different seasons on the Gurbantünggüt Desert.
ISSN:0197-9337
1096-9837
DOI:10.1002/esp.5182