Impact of freeze–thaw cycling on the stability and turnover of black soil aggregates

•Revealing the effects of freeze–thaw cycles on aggregates under natural conditions.•Aggregate stability increased in autumn and decreased in spring.•MWD increased by 15.58% in autumn and decreased by 9.47% in spring.•Each particle size aggregate mainly broke down to its next grade aggregate. During...

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Bibliographic Details
Published in:Geoderma 2024-09, Vol.449, p.117004, Article 117004
Main Authors: Zhang, Yupeng, Fu, Yu, Xu, Jinzhong, Li, Yu, Zhao, Yikai, Wei, Siyu, Liu, Bingjie, Zhang, Xiaoya, Lei, Hanzhe, Shao, Shuai
Format: Article
Language:English
Subjects:
Aggregate processing damage rate
Aggregate turnover
In situ dynamic monitoring
Rare earth oxide (REO)
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Summary:•Revealing the effects of freeze–thaw cycles on aggregates under natural conditions.•Aggregate stability increased in autumn and decreased in spring.•MWD increased by 15.58% in autumn and decreased by 9.47% in spring.•Each particle size aggregate mainly broke down to its next grade aggregate. During freeze–thaw cycling, aggregates undergo a dynamic change in breakdown–formation (turnover), however, how the turnover occurs between aggregates of various particle sizes is not clear. To clarify the influence of freeze–thaw cycling on the dynamic changes in the particle size of soil aggregates, soil aggregates from the Black Soil Region of Northeast China were selected as the research objects. The study conducted in situ dynamic monitoring experiments, innovatively applying the rare earth oxide (REO) tracer method to natural conditions of freeze–thaw cycles (autumn freeze–thaw period, freezing period, and spring freeze–thaw period), accurately tracking the turnover paths and quantifying the turnover rates between aggregates of various particle sizes. The results revealed that the total value of the formation paths of the 2–5 mm aggregates and 0.25–2 mm aggregates increased during the autumn freeze–thaw period. The number of freeze–thaw cycles and accumulated snowfall were significantly positively correlated with aggregate stability, with an increase in the number of freeze–thaw cycles and accumulated snowfall resulting in an increase in the proportion of aggregates > 0.25 mm, which improved aggregate stability. In addition, the total value of the breakdown path of macro-aggregates increased during the spring freeze–thaw cycling period. Soil moisture was significantly negatively correlated with aggregate stability, with increased soil moisture resulting in a decrease in the percentage of aggregates > 0.25 mm, which resulted in a decrease in aggregate stability. The study can provide a reference understanding for the effects of freeze–thaw cycles on the structure of black soil and provide a theoretical basis for improving the quality of arable land.
ISSN:0016-7061
1872-6259
DOI:10.1016/j.geoderma.2024.117004