Macroporosity of a Typic Argiudoll with different cropping intensity under no-tillage

IF 2 Q3 SOIL SCIENCE Spanish Journal of Soil Science Pub Date : 2018-07-13 DOI:10.3232/SJSS.2018.V8.N2.06
F. Kraemer, H. Morrás
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引用次数: 11

Abstract

Soil macropores are dominant pathways of water flow and their impact on hydraulic properties is directly related to their geometrical and topological characteristics. A number of field and micromorphological analysis have shown that agriculture management under no-tillage promotes the development of a microstructure characterized by platy aggregates and horizontal planes in the topsoil, together with a densification at a subjacent layer, thus raising questions about physical properties and water dynamics under this system of cultivation. Moreover, scarce information is available about the evolution of pore architecture and physical parameters in soils under no-till with different cropping intensity. The objective of this work was to evaluate soil porosity in a silty loam A horizon of a Typic Argiudoll (Monte Buey series) of northern Pampa Region (Argentina) under two no-tilled contrasting managements: Good Agricultural Practices (GAP) –highly intensified cropping sequence including corn and wheat in addition to soybean-, Poor Agricultural Practices (PAP) -simplified crop sequence, with predominance of soybean- and a Natural Environment (NE) as reference. Topsoil porosity was assessed by micromorphology, micromorphometry and water retention curves approach, and the values obtained were related to some physical and chemical variables. Results of the morphological analysis revealed important differences between both agricultural treatments. In the surface layer in GAP, platy aggregates are thick and result from the cohesion of rounded microaggregates of biological origin; in PAP they are thin and dense, resulting mostly from compaction of individual soil particles and small microaggregates. A soil densification is evident in both agricultural treatments at 5-10 cm depth, although the morphology and size of aggregates and pores also differ between them. Micromorphometric analyses have shown differences in total macroporosity as well as in the size, morphology and orientation of macropores between both treatments. Macroporosity values obtained by digital methods were coincidently reflected by the pressure plate method. Porosity variables measured by digital analysis, in particular elongated pores and pore orientation, appear more sensitive than other soil properties (total carbon, aggregate stability, bulk density) in discriminating treatments. Although no-till cultivation led to the formation of platy microstructures and a decrease of soil porosity compared to NE, both agricultural treatments presented optimal values of Ks and water movement was not impaired. As expected, all morphological and analytical soil variables were better in the NE treatment. In addition, it was interesting to verify that the values of several parameters were close or similar between GAP and NE. Even when more intensified crop sequence (GAP) increases machinery traffic, morphological, physical and chemical soil properties were here improved compared to PAP. In this case, the higher proportion of different graminea into the agricultural cycle, besides its effect on the development of root biopores, seems to promote a higher fauna activity which effectively counteracts the vertical mechanical compression produced by traffic. These results suggest that, in addition to the known benefits of non-tillage on soil conservation, the improvement of various soil properties could be achieved by integrating this method of cultivation with suitable agricultural managements.
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免耕条件下不同种植强度典型松果的宏观孔隙度
土壤大孔隙是水流的主要通道,其对水力特性的影响与其几何和拓扑特征直接相关。大量田间和微观形态分析表明,免耕下的农业管理促进了表层土中以平板状聚集体和水平面为特征的微观结构的发展,以及下层的致密化,从而引发了对该耕作系统下的物理特性和水动力学的问题。此外,关于不同种植强度免耕条件下土壤孔隙结构和物理参数的演变,目前还缺乏相关信息。这项工作的目的是在两种不同的免耕管理下评估潘帕地区(阿根廷)北部典型Argiudoll(Monte Buey系列)粉质壤土a层的土壤孔隙度:良好农业规范(GAP)-高度强化的种植顺序,包括玉米和小麦以及大豆,不良农业规范(PAP)-简化的种植顺序,以大豆优势与自然环境(NE)为参考。通过微观形态、微观形态和保水曲线法评估表层土的孔隙率,所得值与一些物理和化学变量有关。形态分析结果显示两种农业处理之间存在重要差异。在GAP的表层,板状聚集体较厚,是由生物来源的圆形微聚集体凝聚而成;在PAP中,它们又薄又密,主要是由于单个土壤颗粒和小微团聚体的压实。在5-10厘米深的两种农业处理中,土壤致密化是明显的,尽管它们之间的团聚体和孔隙的形态和大小也不同。微观形态分析显示,两种处理之间的总大孔率以及大孔的大小、形态和方向存在差异。通过数字方法获得的宏观孔隙率值通过压板方法得到了一致的反映。通过数字分析测量的孔隙度变量,特别是细长孔隙和孔隙方向,在判别处理中似乎比其他土壤特性(总碳、骨料稳定性、堆积密度)更敏感。尽管与NE相比,免耕栽培导致了平板状微观结构的形成和土壤孔隙度的降低,但两种农业处理都呈现出最佳的Ks值,水分运动没有受到影响。正如预期的那样,NE处理的所有形态和分析土壤变量都更好。此外,有趣的是,验证了GAP和NE之间几个参数的值接近或相似。即使更强化的作物序列(GAP)增加了机械流量,与PAP相比,土壤的形态、物理和化学性质也有所改善。在这种情况下,不同禾本科植物在农业循环中所占的比例越高,除了对根系生物矿石的发育产生影响外,似乎还促进了更高的动物活动,从而有效地抵消了交通产生的垂直机械压缩。这些结果表明,除了已知的免耕对土壤保持的好处外,还可以通过将这种耕作方法与适当的农业管理相结合来改善各种土壤性质。
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来源期刊
CiteScore
2.20
自引率
0.00%
发文量
13
期刊介绍: The Spanish Journal of Soil Science (SJSS) is a peer-reviewed journal with open access for the publication of Soil Science research, which is published every four months. This publication welcomes works from all parts of the world and different geographic areas. It aims to publish original, innovative, and high-quality scientific papers related to field and laboratory research on all basic and applied aspects of Soil Science. The journal is also interested in interdisciplinary studies linked to soil research, short communications presenting new findings and applications, and invited state of art reviews. The journal focuses on all the different areas of Soil Science represented by the Spanish Society of Soil Science: soil genesis, morphology and micromorphology, physics, chemistry, biology, mineralogy, biochemistry and its functions, classification, survey, and soil information systems; soil fertility and plant nutrition, hydrology and geomorphology; soil evaluation and land use planning; soil protection and conservation; soil degradation and remediation; soil quality; soil-plant relationships; soils and land use change; sustainability of ecosystems; soils and environmental quality; methods of soil analysis; pedometrics; new techniques and soil education. Other fields with growing interest include: digital soil mapping, soil nanotechnology, the modelling of biological and biochemical processes, mechanisms and processes responsible for the mobilization and immobilization of nutrients, organic matter stabilization, biogeochemical nutrient cycles, the influence of climatic change on soil processes and soil-plant relationships, carbon sequestration, and the role of soils in climatic change and ecological and environmental processes.
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