Interaction between POM and pore structure during straw decomposition in two soils with contrasting texture

IF 6.1 1区 农林科学 Q1 SOIL SCIENCE
Tianyu Ding , Zichun Guo , Yongqi Qian , Yuekai Wang , Fahui Jiang , Zhongbin Zhang , Xinhua Peng
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引用次数: 0

Abstract

Particulate organic matter (POM) decomposition is influenced by soil pore structure, and the volume loss associated with POM decomposition might also promote the generation of new pores. However, the interaction between POM decomposition and soil pore structure remains unclear. Therefore, the objective of this study was to explore this interaction during straw decomposition. A 57-day soil incubation experiment was conducted using 13C-labelled maize straw in both Shajiang black soil and Fluvo-aquic soil, with two bulk densities (1.2 g/cm3, T1.2 and 1.5 g/cm3, T1.5). The loss of POM volume and the changes in soil pore structure, both before and after the incubation experiment, were quantified using X-ray micro-computed tomography (μCT). The results showed that there was a significantly greater volume loss of POM in Shajiang black soil (POM volume loss: 58.2–75.0 %) compared to Fluvo-aquic soil (34.0 %). Within the Shajiang black soil, decomposition of POM and the release of respired 13CO2 were notably higher in the soil from the T1.2 treatment compared to the T1.5 treatment (P<0.05), while no significant difference was observed in Fluvo-aquic soil. Image-based porosity and mean pore distance emerged as primary determinants of POM variations in Shajiang black soil. Furthermore, our results underscore the positive role of pores ranging from 50 to 300 μm in diameter (Ø) in facilitating rapid POM decomposition, as evidenced by a higher 13CO2 release. In Shajiang black soil, POM decomposition increased the porosity of 100–200 μm, 200–300 μm, and >300 μm Ø pores by 26.2 %, 51.8 % and 82.9 %, respectively, in the T1.2 treatment (P<0.05), and 50–100 μm Ø pores by 24.7 % in the T1.5 treatment (P<0.05). Our findings emphasize the significance of 100–300 μm Ø pores in gas transport and fresh POM decomposition, highlighting the pivotal role of POM decomposition in shaping soil pore structure.

两种质地截然不同的土壤在秸秆分解过程中 POM 与孔隙结构之间的相互作用
颗粒有机物(POM)的分解受土壤孔隙结构的影响,与 POM 分解相关的体积损失也可能促进新孔隙的生成。然而,POM 分解与土壤孔隙结构之间的相互作用仍不清楚。因此,本研究旨在探索秸秆分解过程中的这种相互作用。研究人员使用 13C 标记的玉米秸秆在两种容重(1.2 克/立方厘米,T1.2;1.5 克/立方厘米,T1.5)的沙澧黑土和氟水土中进行了为期 57 天的土壤培养实验。采用 X 射线显微计算机断层扫描(μCT)对培养实验前后 POM 体积的损失和土壤孔隙结构的变化进行了量化。结果表明,沙江黑土的 POM 体积损失率(POM 体积损失率:58.2-75.0%)明显高于氟水土(34.0%)。在沙江黑土中,与 T1.5 处理相比,T1.2 处理土壤中 POM 的分解和 13CO2 的呼吸释放量明显更高(P<0.05),而在氟水土壤中未观察到显著差异。基于图像的孔隙度和平均孔距是沙江黑土中 POM 变化的主要决定因素。此外,我们的研究结果还强调了直径(Ø)在 50 到 300 μm 之间的孔隙在促进 POM 快速分解方面的积极作用,较高的 13CO2 释放量就证明了这一点。在沙江黑土中,POM 分解使直径为 100-200 μm、200-300 μm 和 >300 μm 的孔隙度在 T1.2 处理中分别增加了 26.2%、51.8% 和 82.9%(P<0.05),使直径为 50-100 μm 的孔隙度在 T1.5 处理中增加了 24.7%(P<0.05)。我们的发现强调了直径为 100-300 μm 的孔隙在气体传输和新鲜 POM 分解中的重要性,突出了 POM 分解在塑造土壤孔隙结构中的关键作用。
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来源期刊
Soil & Tillage Research
Soil & Tillage Research 农林科学-土壤科学
CiteScore
13.00
自引率
6.20%
发文量
266
审稿时长
5 months
期刊介绍: Soil & Tillage Research examines the physical, chemical and biological changes in the soil caused by tillage and field traffic. Manuscripts will be considered on aspects of soil science, physics, technology, mechanization and applied engineering for a sustainable balance among productivity, environmental quality and profitability. The following are examples of suitable topics within the scope of the journal of Soil and Tillage Research: The agricultural and biosystems engineering associated with tillage (including no-tillage, reduced-tillage and direct drilling), irrigation and drainage, crops and crop rotations, fertilization, rehabilitation of mine spoils and processes used to modify soils. Soil change effects on establishment and yield of crops, growth of plants and roots, structure and erosion of soil, cycling of carbon and nutrients, greenhouse gas emissions, leaching, runoff and other processes that affect environmental quality. Characterization or modeling of tillage and field traffic responses, soil, climate, or topographic effects, soil deformation processes, tillage tools, traction devices, energy requirements, economics, surface and subsurface water quality effects, tillage effects on weed, pest and disease control, and their interactions.
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