Synergy Between Woody Peat and Bentonite Alters Stability of Soil Organic Carbon in Coarse Soil by Enhancing Capacity for Soil Aggregation and Hydro‐Physical Properties

IF 3.6 2区农林科学 Q2 ENVIRONMENTAL SCIENCES

Land Degradation & Development Pub Date : 2024-10-30 DOI:10.1002/ldr.5363

Xi Wang, Jun Fan, Huan Wang, Mengge Du

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Abstract

Coarse soil has a poor structure and is susceptible to wind and water erosion, thereby making it difficult to maintain the soil organic carbon (SOC) content. Woody peat (WP) is an organic material that can increase the SOC content of the soil, while clay materials can rapidly enhance the capacity for soil aggregate formation. In order to explore the synergistic effects of WP and clay materials (bentonite and red clay) on the aggregate structure and hydro‐physical properties of coarse soil, as well as the mechanism associated with SOC mineralization (ΔSOC), we conducted an incubation study using lou soil (L0) and loessial soil (H0) with three treatments: addition of WP alone (LW, HW), mixture of WP and bentonite (LWB, HWB), and mixture of WP and red clay (LWR, HWR). The three treatments enhanced the proportion of macroaggregate (> 2 mm) and aggregate stability of the two soils, and optimized the water retention and ventilation performance. The highest aggregate stability of LWB and HWB can be attributed to the positive synergistic effect of WP and bentonite, and bentonite was more effective than red clay due to its crystal structure. The results also showed that the ΔSOC values were significantly lower under LWB and HWB than those under WP addition alone and adding the mixture of WP and red clay (p < 0.05). Moreover, partial least squares path modeling analysis showed that the hydro‐physical properties of the two improved soils inhibited SOC mineralization (p > 0.05), whereas particulate organic carbon (POC) content significantly accelerated SOC mineralization (p < 0.01). The synergistic effect of clay materials increased mineral‐associated organic carbon (MAOC), which was beneficial to maintain the long‐term effectiveness of WP. Overall, our results demonstrated that the synergistic use of WP and bentonite enhanced the aggregate stability and hydro‐physical properties of coarse soil and improved SOC storage capacity. These results provide scientific and theoretical guidance to facilitate the rapid improvement of coarse soil through engineering measures in arid and semi‐arid areas with water and fertilizer limitations.

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木质泥炭与膨润土的协同作用可通过增强土壤团聚能力和水文物理特性来改变粗粒土壤中土壤有机碳的稳定性

粗粒土壤结构差，易受风蚀和水蚀，因此难以保持土壤有机碳（SOC）含量。木质泥炭（WP）是一种有机材料，可以增加土壤中的 SOC 含量，而粘土材料则能迅速提高土壤团聚体的形成能力。为了探索可湿性粉剂和粘土材料（膨润土和红粘土）对粗粒土的团聚结构和水物理性质的协同作用，以及与 SOC 矿化（ΔSOC）相关的机制，我们使用耧斗土（L0）和黄土（H0）进行了一项培养研究，其中有三种处理方法：单独添加可湿性粉剂（LW、HW）、可湿性粉剂与膨润土的混合物（LWB、HWB）以及可湿性粉剂与红粘土的混合物（LWR、HWR）。这三种处理方法提高了两种土壤的大集料（> 2 mm）比例和集料稳定性，并优化了保水性和透气性能。LWB 和 HWB 的集料稳定性最高，这归因于可湿性粉剂和膨润土的正协同效应，而膨润土因其晶体结构比红土更有效。结果还表明，在 LWB 和 HWB 条件下，ΔSOC 值明显低于单独添加可湿性粉剂和添加可湿性粉剂与红土混合物条件下的ΔSOC 值（p < 0.05）。此外，偏最小二乘法路径模型分析表明，两种改良土壤的水物理特性抑制了 SOC 矿化（p >；0.05），而颗粒有机碳（POC）含量则明显加速了 SOC 矿化（p <；0.01）。粘土材料的协同效应增加了矿物相关有机碳（MAOC），有利于维持可湿性粉剂的长期有效性。总之，我们的研究结果表明，可湿性粉剂和膨润土的协同使用增强了粗粒土壤的团聚稳定性和水物理性质，提高了 SOC 的储存能力。这些结果为干旱和半干旱地区通过工程措施快速改良受水肥限制的粗粒土壤提供了科学和理论指导。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Land Degradation & Development 农林科学-环境科学

CiteScore

7.70

自引率

8.50%

发文量

379

审稿时长

5.5 months

期刊介绍： Land Degradation & Development is an international journal which seeks to promote rational study of the recognition, monitoring, control and rehabilitation of degradation in terrestrial environments. The journal focuses on: - what land degradation is; - what causes land degradation; - the impacts of land degradation - the scale of land degradation; - the history, current status or future trends of land degradation; - avoidance, mitigation and control of land degradation; - remedial actions to rehabilitate or restore degraded land; - sustainable land management.