Culturable Microorganism Diversity and Physicochemical Properties of Soil in the Reclamation Area of Coal Mine Wasteland

doi:10.11924/j.issn.1000-6850.casb2022-0249

Abstract

Abstract:

To evaluate the effect of different vegetation on soil ecological restoration in coal mine wasteland reclamation area, this paper used traditional methods to study soil microbial diversity and physicochemical properties of peach forest, wasteland, cedar forest, plum forest and green manure vegetation in reclamation area. The results are as follows. (1) The soil physicochemical properties of different vegetation were significantly different. The area was extremely rich in total phosphorus, lack in available nitrogen, total potassium and organic matter, and with medium level of available phosphorus and pH<5.8. (2) Among the three major microorganisms in this area, the proportion of bacteria was 87.58%-99.57%, which was the dominant colony under various vegetation, and there was a small difference under different vegetation; the proportions of fungi and actinomycetes had large difference, and the B/F value and the total number of the three major microorganisms of green manure vegetation were the largest. (3) The most culturable functional microorganisms in this area were ammoniated bacteria, iron bacteria and nitrogen-fixing bacteria, but there were significant differences of the amount of bacteria among different vegetation, and the dominant functional microorganisms under different vegetation were different, such as iron bacteria and nitrogen-fixing bacteria in peach forest, iron bacteria in wasteland, ammoniated bacteria and iron bacteria in cedar forest, ammoniated bacteria and nitrogen-fixing bacteria in plum forest, and ammoniated bacteria in green manure vegetation. The total number of culturable functional bacteria in cedar forest and green manure vegetation was 4.50 times and 3.48 times that of peach forest, respectively. (4) Under different vegetation types, the diversity of the three major microorganisms was higher in cedar forest, which was 0.71; the diversity index of some culturable functional bacteria was higher in wasteland, which was 1.52; ammoniated bacteria were mostly affected by soil physicochemical properties, followed by inorganic phosphorus bacteria and organic phosphorus bacteria. This study found that the dominant functional microorganisms under different vegetation in this area were ammoniated bacteria, iron bacteria and nitrogen-fixing bacteria, and could provide some reference for the restoration of coal mine reclaimed soil.

Key words: coal mine wasteland, vegetation type, soil physicochemical properties, culturable microorganisms, diversity

ZHENG Wei, YUAN Longzhen, WANG Jianhua, YANG Yao, WU Chuanguang, HUANG Ying, YOU Ping, XUE Xiaohui. Culturable Microorganism Diversity and Physicochemical Properties of Soil in the Reclamation Area of Coal Mine Wasteland[J]. Chinese Agricultural Science Bulletin, 2023, 39(7): 81-87.

Figures/Tables 7

References 44

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土壤类型	海拔/m	东经	北纬	覆土深度/cm
桃树林	1555	106°05′13.16″	27°25′33.65″	20
荒地	1553	106°05′14.14″	27°25′29.12″	20
杉树林	1535	106°05′15.36″	27°25′25.98″	20
李树林	1555	106°05′21.09″	27°25′34.27″	20
绿肥	1500	106°05′30.80″	27°25′21.04″	20

土壤类型	海拔/m	东经	北纬	覆土深度/cm
桃树林	1555	106°05′13.16″	27°25′33.65″	20
荒地	1553	106°05′14.14″	27°25′29.12″	20
杉树林	1535	106°05′15.36″	27°25′25.98″	20
李树林	1555	106°05′21.09″	27°25′34.27″	20
绿肥	1500	106°05′30.80″	27°25′21.04″	20

植被类型	全磷/(g/kg)	速效磷/(mg/kg)	全氮/(g/kg)	速效氮/(mg/kg)	全钾/(g/kg)	速效钾/(mg/kg)	有机质/(g/kg)	pH
桃树林	7.97±0.14aA	16.91±0.22dC	1.10±0.03cC	49.85±1.01bB	5.30±0.09cC	139.09±2.42cC	10.99±0.30aA	5.53±0.03bB
荒地	7.03±0.04cC	17.37±0.26dC	2.34±0.05aA	46.62±0.24bB	8.54±0.16aA	163.70±2.71aA	8.96±0.19bB	5.54±0.03bB
杉树林	7.48±0.13bB	34.58±0.86aA	1.13±0.04cC	39.47±0.27cC	4.68±0.12dD	141.71±4.73cBC	4.19±0.10dD	5.28±0.15cC
李树林	7.42±0.19bB	18.38±0.18cC	1.56±0.06bB	46.71±2.04bB	5.67±0.23bB	128.20±2.93dD	2.97±0.08eE	5.76±0.03aA
绿肥	7.38±0.05bB	25.95±0.81bB	1.15±0.02cC	87.99±3.88aA	4.67±0.03dD	149.86±2.63bB	6.93±0.04cC	5.23±0.01cC

植被类型	全磷/(g/kg)	速效磷/(mg/kg)	全氮/(g/kg)	速效氮/(mg/kg)	全钾/(g/kg)	速效钾/(mg/kg)	有机质/(g/kg)	pH
桃树林	7.97±0.14aA	16.91±0.22dC	1.10±0.03cC	49.85±1.01bB	5.30±0.09cC	139.09±2.42cC	10.99±0.30aA	5.53±0.03bB
荒地	7.03±0.04cC	17.37±0.26dC	2.34±0.05aA	46.62±0.24bB	8.54±0.16aA	163.70±2.71aA	8.96±0.19bB	5.54±0.03bB
杉树林	7.48±0.13bB	34.58±0.86aA	1.13±0.04cC	39.47±0.27cC	4.68±0.12dD	141.71±4.73cBC	4.19±0.10dD	5.28±0.15cC
李树林	7.42±0.19bB	18.38±0.18cC	1.56±0.06bB	46.71±2.04bB	5.67±0.23bB	128.20±2.93dD	2.97±0.08eE	5.76±0.03aA
绿肥	7.38±0.05bB	25.95±0.81bB	1.15±0.02cC	87.99±3.88aA	4.67±0.03dD	149.86±2.63bB	6.93±0.04cC	5.23±0.01cC

植被类型	全磷	速效磷	全氮	速效氮	全钾	速效钾	有机质
桃树林	一级/极丰	三级/中等	三级/中等	五级/较缺	五级/较缺	三级/中等	四级/缺乏
荒地	一级/极丰	三级/中等	一级/极丰	五级/较缺	五级/较缺	二级/较丰	五级/较缺
杉树林	一级/极丰	二级/较丰	三级/中等	五级/较缺	六级/极缺	三级/中等	六级/极缺
李树林	一级/极丰	三级/中等	二级/中等	五级/较缺	五级/较缺	三级/中等	六级/极缺
绿肥	一级/极丰	二级/较丰	三级/中等	四级/缺乏	六级/极缺	二级/较丰	五级/较缺