[1]YOU Yang,TIAN Peng,YANG Wenjin,et al.Influence of Coal Mining Subsidence on Sandy Geomorphology and Vegetation Habitat in Sandy Area[J].Research of Soil and Water Conservation,2021,28(02):88-92+98.
Copy
Influence of Coal Mining Subsidence on Sandy Geomorphology and Vegetation Habitat in Sandy Area
Research of Soil and Water Conservation[ISSN 1005-3409/CN 61-1272/P] Volume:
28
Number of periods:
2021 02
Page number:
88-92+98
Column:
Public date:
2021-02-06
- Title:
- Influence of Coal Mining Subsidence on Sandy Geomorphology and Vegetation Habitat in Sandy Area
- CLC:
- X37
- DOI:
- -
- Abstract:
- In order to explore the ‘secondary desertification' problems and countermeasures caused by coal mining subsidence in the arid and semi-arid sandy area, through field partition quadrat survey, using statistical methods, detailed research on the subsidence collapse edge, the central subsidence and subsidence basin led to the collapse of central crack width and strewn at random, the vegetation of displacement and tilt, dry sand and wind erosion/wind laid situation has carried out. The results show that the width and density of cracks are the smallest in the margin of collapse, the second in the middle of collapse, and the largest in the basin of collapse, whereas the changes of fracture staggering and surface damage are the opposite; the average displacement length of vegetation in the subsidence area is more than 60 cm, and the change of tilt rate is between 5.67 and 28.63; the average depth of main wind erosion/wind laid is up to -30.52 cm/+25.41 cm, which is the most serious in the collapse margin; the displacement length and change of tilt rate of vegetation are in positive linear correlation with the height of collapse fracture and the fragmentation of surface; the average thickness of the dry sand layer at the collapse edge was more than 14 cm, which increased by 4~6 cm compared with the control, while the changes in the central subsidence and the subsidence basin were about 11 cm, which increased by 1~4 cm compared with the non-collapse; the wind erosion rate of the collapse edge is as high as 83.34%, followed by 52.06% in the central subsidence, and is 51.84% in subsidence basin. The comprehensive analysis shows that the collapse edge has the strongest impact on sandy land surface and vegetation habitat, and is the key area for ecological restoration. It is suggested to carry out zonal control in time after coal mining collapse and take appropriate measures to avoid the occurrence of ‘secondary desertification' in the subsidence area.
- References:
-
[1] 赵国平,史社强,李军保,等.毛乌素沙地采煤塌陷区土壤水分空间变异研究[J].水土保持学报,2017,31(6):90-93,219.
[2] 赵国平,朱建军,张继平,等.神府煤田采煤塌陷引起的生态问题探讨[J].干旱区资源与环境,2017,31(9):103-107.
[3] 赵国平,李晖,李旭祥,等.神府煤田风沙区采煤塌陷地表环境动态变化的综合评价[J].西安交通大学学报,2012,46(5):137-142.
[4] 赵国平,毕银丽,杨伟,等.神府煤田风沙区采煤塌陷对粒度成分特征的影响[J].中国沙漠,2015,35(6):1461-1466.
[5] 何冰,李廷亮,栗丽,等.采煤塌陷区复垦土壤团聚体碳氮分布对施肥的响应[J].水土保持学报,2018,32(4):184-189,196.
[6] 王健,高永,魏江生,等.采煤塌陷对风沙区土壤理化性质影响的研究[J].水土保持学报,2006,20(5):52-55.
[7] 赵红梅.采矿塌陷条件下包气带土壤水分分布与动态变化特征研究[D].北京:中国地质科学院,2006.
[8] 崔利强,吴波,杨文斌,等.毛乌素沙地东南缘不同植被盖度下土壤水分特征分析[J].干旱区资源与环境,2010,24(2):177-182.
[9] 安慧,安钰.毛乌素沙地南缘沙柳灌丛土壤水分及水量平衡[J].应用生态学报,2011,22(9):2247-2252.
[10] 孙建华,刘建军,康博文,等.陕北毛乌素沙地土壤水分时空变异规律研究[J].干旱区农业研究,2009,27(2):244-247.
[11] 舒培仙,牛东风,李保生,等.毛乌素沙地现代沙丘沙的粒度特征及其意义[J].中国沙漠,2016,36(1):158-166.
[12] 尚爱军,卜耀军,艾海舰,等.榆林沙区土壤水分时空格局及动态变化规律研究[J].水土保持学报,2008,22(4):86-89.
- Similar References:
Memo
-
Last Update:
2021-02-10