Chemical diversity and molecular signature of soil humic fractions used as proxies of soil quality under contrasted tillage management

IF 2 Q3 SOIL SCIENCE
M. Panettieri, M. Jiménez-González, L. L. Sosa, G. Almendros, E. Madejón
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引用次数: 2

Abstract

Increasing food production while avoiding the progressive degradation of agricultural soils has become one of the major challenges at a global level. In consequence, the development of sustainable tillage methodologies or cultivation strategies is an important subject of current research. In fact, it has been observed that the implementation of reduced tillage (RT) vs. traditional tillage (TT) in the long term not only improves soil physicochemical properties but also global soil quality in terms of soil health. In particular, the increase of the soil organic carbon (SOC) content under RT conditions is one of the most important factors, but there is little information about the chemical composition and humification level of this carbon, and thus about its persistence at long-term. This is of particular importance considering the policies of carbon sequestration and climate change mitigation, such as the “4 per 1000” initiative. In this study, molecular-level characterization of the humic acid (HA) and fulvic acid (FA) fractions isolated from a soil after 19 years under RT and TT practices was carried out. This study would provide objective descriptors of the impact of these two tillage practices in the chemical composition of the resulting SOC. With this purpose, the potential of Fourier Transform Ion Cyclotron Resonance Mass Spectrometry (FTICR-MS) for assessing changes in the molecular assemblages released from the humic fractions (HA and FA) was examined. The results showed enhanced diversity and chemical richness (expressed as number of molecular formulas) in the composition of SOC under RT. Different tillage-specific compound classes were associated with both tillage practices. As a whole, the humic fraction showed a higher proportion of molecular formulas for lipid and hydroaromatic families in the case of RT compared to TT, while the same fraction under TT showed a greater richness of oxidized protein-derived formulas than RT. In the case of FAs, a similar pattern was observed for hydroaromatic and protein-derived formulas, but the proportion of molecular formulas assigned to unsaturated lipids was higher in TT than in RT. In addition, increased number of formulas for aromatic and condensed aromatic compounds was observed in FAs under TT respect to RT.
对比耕作管理下土壤腐殖质组分的化学多样性和分子特征
在避免农业土壤逐渐退化的同时增加粮食产量已成为全球一级的主要挑战之一。因此,可持续耕作方法或耕作策略的发展是当前研究的一个重要课题。事实上,已经观察到,与传统耕作(TT)相比,长期实施减少耕作(RT)不仅改善了土壤的物理化学性质,而且从土壤健康角度改善了全球土壤质量。特别是,在RT条件下,土壤有机碳(SOC)含量的增加是最重要的因素之一,但关于这种碳的化学成分和腐殖化水平,以及其长期持久性的信息很少。考虑到碳固存和减缓气候变化的政策,例如“千分之四”倡议,这一点尤为重要。在本研究中,对在RT和TT实践下从土壤中分离19年的腐殖酸(HA)和黄腐酸(FA)组分进行了分子水平的表征。本研究将为这两种耕作方式对有机碳化学成分的影响提供客观的描述。为此,研究了傅里叶变换离子回旋共振质谱法(FTICR-MS)评估腐殖组分(HA和FA)释放的分子组合变化的潜力。结果表明,在RT条件下,SOC组成的多样性和化学丰富度(以分子式的数量表示)增强。不同的耕作特定化合物类别与两种耕作方式有关。总的来说,与TT相比,在RT的情况下,腐殖组分显示出更高比例的脂质和水芳香族分子式,而在TT的情况下相同的组分显示了比RT更丰富的氧化蛋白质衍生式。在FA的情况中,水芳香族和蛋白质衍生式也观察到类似的模式,但TT中分配给不饱和脂质的分子式的比例高于RT。此外,相对于RT,在TT下的FA中观察到芳香族和稠合芳香族化合物的分子式数量增加。
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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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