干旱砾漠区不同微地貌单元土壤性状及真菌群落变化特征

doi:10.13866/j.azr.2024.03.07

Abstract

Abstract:

Exploring the characteristics of soil properties, fungal communities, and their driving factors in different microgeomorphic units in arid gravel desert areas is important for the study of fungal community construction mechanisms and practical guidance for targeted ecological damage restoration strategies. In this paper, the changes in soil physicochemical properties, fungal α diversity, and community composition of four microgeomorphic units (wind erosion residual hills, gravel desert Gobi, river valley, and wind sand land) in an arid gravel desert area were compared. The main factors affecting soil fungal communities in different microgeomorphological units in gravel desert areas were explored by combining plant characteristics and micrometeorological factors. Results showed that the soil in the arid gravel desert area was dominated by sandy soil, and wind sand land had the largest sandy content and the smallest clay content, which was contrary to the soil mechanical composition of the river valley. No significant difference in soil bulk density and organic matter content was found between the river valley and the gravel desert Gobi, but their soil bulk density and organic matter content were significantly higher than those of the other two microgeomorphic units. However, the soluble salt content of the river valley was 21.4%, which was significantly lower than that in other microgeomorphic units, but the soil water content was significantly higher by 39.3%. Except for the contents of available N, available K and available P in the gravel desert Gobi and wind erosion residual hills, no significant difference in the available nutrients was found in other microgeomorphological units. In addition, the α diversity of soil fungi, Shannon-Wiener index, Pieloue index, and Simpson index all showed a significant decrease in wind sand land, whereas no significant difference in other microgeomorphological units was found. However, the Chao1 index has no significant difference. At the phylum level, the dominant fungi phyla were Ascomycota and Basidiomycota in different microgeomorphic units. Ascomycota has the largest dominance in the gravel desert Gobi and wind erosion residual hills, and Basidiomycota has the largest proportion in the river valley. At the genera level, Neocamarosporium and Subramaniu in the Wind erosion residual hill, Preussia and Neocamarosporium in the gravel desert Gobi, Aspergillus and Alternaria in the river valley, and Trichophaeopsis and Neocamarosporium in the wind sand land were the dominant genera of soil fungal communities in each geomorphic unit. Soil water content, organic matter, available N, and soluble salts were the common key factors affecting the changes in soil fungal community structure in different microgeomorphic units in an arid gravel desert area. Furthermore, the soil mechanical composition in wind sand land, surface temperature and light radiation intensity of wind erosion residual hills, surface wind speed of gravel desert Gobi, and surface vegetation biomass of river valley were the differentiated ecological factors affecting soil fungal community in each geomorphic unit.

Key words: arid gravel desert area, microgeomorphic units, soil physicochemical properties, soil fungi community, ecological factors

DU Huadong, LIU Yan, BI Yinli, CHE Xuxi, BAI Mengtong. Characteristics of soil properties and fungal community changes in different microgeomorphic units in an arid gravel desert area[J].Arid Zone Research, 2024, 41(3): 421-431.

Figures/Tables 8

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生态因子	风蚀残丘（n=15）	砾漠戈壁（n=15）	河谷（n=15）	风沙地（n=15）
植物覆盖度/%	20.80±6.83ab	18.61±3.93b	32.50±10.52a	19.40±9.0ab
植物密度/（株·m^-2）	36.00±15.87b	31.80±6.79b	220.25±43.31a	61.80±8.62ab
生物量/（g·m^-2）	19.29±2.67a	15.65±2.09a	27.67±5.80a	18.56±2.51a
地表温度/℃	34.12±1.93a	35.70±1.06a	35.35±5.96a	34.92±5.12a
空气温度/℃	32.28±1.98a	31.80±2.33a	32.08±0.18a	33.46±0.34a
地表蒸发量/mm	603.30±65.21a	302.35±28.35a	330.25±18.65a	485.58±52.60a
光辐射强度/（W·m^-2）	930.82±42.29a	735.49±33.68a	938.43±42.70a	923.94±31.57a
地表风速/（m·s^-1）	2.89±1.16a	3.44±2.90a	2.87±1.26a	3.09±2.92a

土壤理化性质		风蚀残丘	砾漠戈壁	河谷	风沙地
土壤机械组成/%	黏粒	10.01±8.45ab	10.19±7.88ab	12.67±6.99a	3.39±2.31b
	粉粒	37.35±19.42a	35.86±16.74a	39.91±19.74a	15.69±6.37b
	砂粒	52.64±27.88ab	53.95±24.39ab	47.42±25.58b	80.92±8.66a
土壤容重/（g·cm^-3）		1.10±0.24b	1.35±0.20ab	1.47±0.15a	1.15±0.16b
pH		9.13±0.56a	8.99±0.41a	9.06±0.29a	9.15±0.60a
土壤含水量/%		2.31±0.04b	2.72±0.01ab	4.29±0.02a	2.78±0.02ab
有机质/（g·kg^-1）		1.49±0.51b	2.80±0.61ab	3.96±0.81a	1.46±0.82b
速效氮/（mg·kg^-1）		61.89±31.03a	26.07±6.47b	45.72±29.11ab	45.60±30.68ab
速效磷/（mg·kg^-1）		0.39±0.13b	0.42±0.14ab	0.49±0.20ab	0.61±0.31a
速效钾/（mg·kg^-1）		64.84±26.13a	27.18±6.81b	44.01±19.19ab	39.61±26.45ab
可溶性盐/%		0.32±0.10ab	0.39±0.09a	0.28±0.07b	0.31±0.06ab

Characteristics of soil properties and fungal community changes in different microgeomorphic units in an arid gravel desert area

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