Wind tunnel simulation of sand fixation efficiency for clustered and horizontally laid Salix psammophila sand barriers

doi:10.7522/j.issn.1000-694X.2025.00231

Journal of Desert Research ›› 2026, Vol. 46 ›› Issue (3): 284-295.DOI: 10.7522/j.issn.1000-694X.2025.00231

Wind tunnel simulation of sand fixation efficiency for clustered and horizontally laid Salix psammophila sand barriers

Tao Zheng¹^,²(), Jianhua Xiao¹, Shijun Ma³, Chao Qin⁴, Meilin Li¹^,², Zhengyi Yao¹()

^1.State Key Laboratory of Ecological Safety and Sustainable Development in Arid Lands，Northwest Institute of Eco-Environment and Resources，Chinese Academy of Sciences，Lanzhou 730000，China
^2.University of Chinese Academy of Sciences，Beijing 100049，China
^3.PowerChina Beijing Engineering Corporation Limited，Beijing 100024，China
^4.Xinjiang Huadian Tianshan Power Generation Company Limited，Hami 839000，Xinjiang，China

Received:2025-04-02 Revised:2025-09-22 Online:2026-05-20 Published:2026-06-11
Contact: Zhengyi Yao

Abstract

Abstract:

This study evaluates the sand fixation efficiency of clustered and horizontally laid sand barriers made from Salix psammophila branches through wind tunnel simulations. The results show that：（1） A distinct deceleration zone formed behind each sand barrier， while a pronounced jet flow region developed above the first barrier. The 1 m×1 m and 1 m×1.5 m barrier configurations demonstrated superior windbreak effectiveness.（2） Under varying wind velocities， the sand surface protected by S. psammophila sand barriers generally exhibits an erosional state. The degree of sand surface erosion beneath these barriers increases significantly with higher wind speeds. Within the grid system formed by S. psammophila sand barriers， the foremost section experiences the most severe erosion， with the intensity gradually diminishing in subsequent sections.（3） The wind-sand flow structure in a wind tunnel without sand barriers exhibits an exponential decay curve. In contrast， the wind-sand flow structure in the presence of sand barriers demonstrates a dynamic distribution， primarily due to the obstruction formed by the barriers， which alters its characteristics compared to the barrier-free scenario.（4） The 1m×1m， 1 m×1.5 m， and 1 m×2 m sand barriers showed sediment accumulation reductions of 100%，79%， 72%， and 51%； 100%， 94%， 89%， and 74%； and 100%， 78%， 76%， and 78% at wind speeds of 8 m·s^-1， 12 m·s^-1， 16 m/s， and 20 m/s， respectively， This suggests that S. psammophila sand barriers exhibit significant sand-fixing potential， with the 1 m×1.5 m configuration showing optimal performance.

Key words: Salix psammophila, clustered and horizontally laid sand barriers, wind tunnel simulation, sand fixation efficiency

CLC Number:

Q151

Tao Zheng, Jianhua Xiao, Shijun Ma, Chao Qin, Meilin Li, Zhengyi Yao. Wind tunnel simulation of sand fixation efficiency for clustered and horizontally laid Salix psammophila sand barriers[J]. Journal of Desert Research, 2026, 46(3): 284-295.

Figures/Tables 12

Fig.1 Layout of Salix psammophila sand barrier in wind tunnel

Fig.2 Schematic diagram of the wind tunnel experiment

Fig.3 Wind speed profile of the wind tunnel

Table 1 Wind Tunnel Measurement Parameters

	高度/cm	风速/（m·s^-1）
风速流场观测	0.3、0.6、1.1、1.6、3.1、6.1、12、20、35、50	8、12、16、20（持续时间为30 s）
输沙量观测	0~60（取50 cm以下数据）	8、12、16、20（持续时间分别为10、10、10、5 min）

Fig.4 Arrangement of measurement points for sand erosion and accumulation characteristics and the 2 cm × 60 cm sand trap

Fig.5 Flow field of 1m×1m clustered and horizontally laid sand barriers

Fig.6 Flow field of 1m×1.5m clustered and horizontally laid sand barriers

Fig.7 Flow field of 1m×2m clustered and horizontally laid sand barriers

Fig.8 Surface erosion conditions of moving sand in Salix psammophila sand barriers under different wind speeds （dashed lines represent the position of the barriers； A：1m×1m sand barriers；B：1m×1.5m sand barriers；C：1 m×2 m sand barriers）

Fig.9 Influence of clustered and horizontally laid Salix psammophila sand barriers on sand erosion and accumulation under different wind speeds

Fig.10 Structure of wind-sand flow impacted by different scale Salix psammophila sand barriers

Fig.11 The Salix psammophila sand barriers in the field at Wantaixing Branch of Ordos General Afforestation farm， Inner Mongolia

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Wind tunnel simulation of sand fixation efficiency for clustered and horizontally laid Salix psammophila sand barriers

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