Effects of Erosion Gully Evolution on Particle Size Distribution and Water Storage Properties in Sloping Cropland of a Black Soil Area

Zhang Ruihao; Xiao Yang; Shao Shegang; Xu Jinzhong; Ni Dong; Qiao Yutong; Zhou Qirui; Fu Xingyue

doi:10.13961/j.cnki.stbctb.2023.02.001

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Effects of Erosion Gully Evolution on Particle Size Distribution and Water Storage Properties in Sloping Cropland of a Black Soil Area

- Effects of Erosion Gully Evolution on Particle Size Distribution and Water Storage Properties in Sloping Cropland of a Black Soil Area
- Bulletin of Soiland Water Conservation Vol. 43, Issue 2, Pages: 1-8(2023)
- 作者机构：
  
  1. 黑龙江大学现代农业与生态环境学院,黑龙江,哈尔滨,150080
  2. 交通运输部公路科学研究所,北京,100088
  3. 黑龙江省水利科学研究院,黑龙江,哈尔滨,150080
- 作者简介：
- 基金信息：
- DOI：10.13961/j.cnki.stbctb.2023.02.001
  CLC： S157.1
- Published：2023
- 稿件说明：
移动端阅览
Zhang Ruihao, Xiao Yang, Shao Shegang, et al. Effects of Erosion Gully Evolution on Particle Size Distribution and Water Storage Properties in Sloping Cropland of a Black Soil Area[J]. Bulletin of Soiland Water Conservation, 2023, 43(2): 1-8.
DOI：

Zhang Ruihao, Xiao Yang, Shao Shegang, et al. Effects of Erosion Gully Evolution on Particle Size Distribution and Water Storage Properties in Sloping Cropland of a Black Soil Area[J]. Bulletin of Soiland Water Conservation, 2023, 43(2): 1-8. DOI： 10.13961/j.cnki.stbctb.2023.02.001.

摘要

[目的

]

研究侵蚀作用对黑土区坡耕地侵蚀沟表层土壤的影响，为该区土壤资源合理运用和区域水土流失治理工作提供理论支持。 [方法

]

以黑龙江省哈尔滨市延寿县不同发育程度侵蚀沟为研究对象，对切沟沟头的沟坡和沟底土壤的粒径分布及蓄水性进行定量描述。 [结果

]

①不同深度处土壤容重、最大吸持贮水量、最大滞留水量、总库容、死库容、最大有效库容差异显著(p＜0.05)。随土层加深，土壤容重增大，贮水量、持水性、有效水分下降。各层最大吸持贮水量占饱和贮水量均约90%，有效水分利用率分别为44.79%和41.87%，侵蚀沟发育对土壤有效水分影响明显。 ②入渗特征总体表现为：初始入渗速率＞30 min入渗速率＞稳定入渗速率，3者在不同编号沟道的A

—A

间随土层的加深，入渗性能下降。在20—40 cm层A

—A

的入渗特征均表现为：CK(对照)＞A

＞A

，呈先下降后上升趋势。随着侵蚀沟的发育，土壤入渗性先下降后上升。 ③侵蚀沟的发育是黏粒含量变化的主要原因，黏粒所占比例在0—40 cm层呈先增大，后减小趋势；砂粒所占比例在0—20 cm土层先减小，后增大，呈粗骨化趋势。 ④土壤退化指数在0—20 cm层表现为：A

＞A

。随侵蚀沟的发育，土壤退化程度加剧，A

土壤退化最为严重。 [结论

]

不同深度的土壤剖面差异是造成黑土土壤物理性质差异的主要原因，随着侵蚀沟的发育，0—20 cm层土壤蓄水性能减弱，土壤退化严重。

Abstract

[Objective] The effects of erosion on the surface soil of erosion gullies in sloping cropland soils in a black soil area were studied in order to provide theoretical support for the rational utilization of soil resources and regional soil and water conservation work in black soil areas. [Methods] The study was conducted on erosion gullies with different degrees of development in Yanshou County

Harbin City

Heilongjiang Provicne. Particle size distribution and water storage properties of soil on the slope

at the bottom of the gullies and at the head of the gullies were quantitatively described. [Results] ① Soil bulk density

maximum water-storage capacity

maximum water-retention capacity

total storage capacity

dead storage capacity

and maximum effective storage capacity at different depths were significantly different (p＜0.05). As soil depth increased

soil bulk density also increased

and water-storage

water-retention

and effective water storage capacity decreased. Each layer had a maximum water-storage capacity of about 90% of its saturated capacity

and the effective water utilization rates were 44.79% and 41.87%

respectively. The development of erosion gullies had a clear influence on effective soil water. ② The infiltration characteristics generally showed that the initial infiltration rate＞the 30-minute infiltration rate＞the stable infiltration rate. As soil depth increased

the infiltration characteristics of the three indicators decreased between gully A2 and A4 for different erosion degree gullies. In the 20—40 cm layer

the infiltration characteristics of gully A1 to A4 followed the order of CK (control group)＞ gully A1＞ gully A4＞ gully A2＞ gully A3. Infiltration initially declined and then increased. With the development of the erosion gully

soil infiltration decreased and then increased. ③ The development of erosion gullies was the main reason for the change in clay content. The percentage of clay in the 0—40 cm layer tended to increase first and then decrease. The percentage of sand in the 0—20 cm layer tended to decrease first and then increase

showing a trend toward increased coarseness. ④ The soil degradation index followed the order of gully A1＞ gully A2＞ gully A3＞ gully A4 in the 0—20 cm layer. Soil degradation increased with the development of erosion gullies. Soil degradation was most severe in gully A4. [Conclusion] The differences in soil profiles was the main reason for the differences in physical properties of black soil. Soil water-holding capacity in the 0—20 cm layer was weakened and soil degradation became severe as erosion gullies developed.

关键词

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