Joeri Kaal , Antonio Martínez Cortizas , Gerrit Angst , Cynthia Kallenbach , Cruz Ferro Vázquez , Felipe Criado-Boado
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The objective of this study was to determine how the different drivers of persistent SOM formation influenced the formation of these organic-rich soils. For this purpose, we use Holocene (∼9000 yrs) molecular composition records obtained from pyrolysis-GC–MS (Py-GC–MS) and thermally assisted hydrolysis and methylation (THM-GC–MS). The results emphasize three pathways to stability (i.e., persistence on millennial timescales): 1) palaeofires that generated recalcitrant pyrogenic SOM, 2) release of root-derived aliphatic macromolecules (suberin-like SOM), and 3) formation of microbial necromass. Pathways 1 and 2 are controlled by land use: Pathway 1 was relatively important under intense anthropogenic fire regimes and pyrophytic shrubland expansion; Pathway 2 was stimulated during early forest phases and under pasture conditions, when past societies focused vegetation management on grazing instead of fire; Pathway 3 was controlled by binding with aluminium-dominated mineral phases. However, we found indications that Pathway 2 (suberin input and preservation) relied partially on sorptive preservation as well. Aided by structured equation modeling (SEM), we show that the formation of persistent SOM pools was driven by balanced weights of i) microbial <em>vs.</em> plant-derived SOM and ii) intrinsic chemical properties of SOM (recalcitrance continuum) <em>vs.</em> mineral binding/occlusion, which varied in keeping with interactions between past land use, topography and vegetation. 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引用次数: 0
摘要
了解长期持久的土壤有机质(SOM)的形成是优化土壤管理和预测陆地有机碳(OC)库对气候变化的响应的关键,然而我们对不同稳定途径(如再钙化和矿物结合)的土壤类型权重的了解还很零碎。大西洋欧洲(Haplic Umbrisol [冲积/超湿润])的冲积斜坡沉积物由于其地层结构而特别富含 SOM(矿质土壤高达 2 米,OC 含量大于 5%),是包括 SOM 形成途径在内的古环境条件的档案。本研究的目的是确定持久性 SOM 形成的不同驱动因素如何影响这些富含有机质土壤的形成。为此,我们使用了通过热解-气相色谱-质谱(Py-GC-MS)和热助水解和甲基化(THM-GC-MS)获得的全新世(9000 年)分子成分记录。研究结果强调了实现稳定性(即在千年时间尺度上的持续性)的三种途径:1) 古火产生了难降解的热源 SOM;2) 根衍生脂肪族大分子(类单宁 SOM)的释放;3) 微生物坏死物质的形成。途径 1 和 2 受土地利用的控制:途径 1 在强烈的人为火灾制度和火烧灌木林扩张的情况下相对重要;途径 2 在早期森林阶段和牧场条件下受到刺激,因为过去的社会将植被管理的重点放在放牧而不是火灾上;途径 3 受控于与铝为主的矿物相的结合。不过,我们发现有迹象表明,途径 2(单宁的输入和保存)也部分依赖于吸附性保存。在结构方程建模(SEM)的辅助下,我们发现持久性 SOM 池的形成是由以下因素的平衡加权驱动的:i)微生物植物衍生 SOM;ii)SOM 的内在化学特性(再降解连续性)矿物结合/吸附,这些因素随过去土地利用、地形和植被之间的相互作用而变化。这些发现与仅通过微生物尸体的吸附/闭塞保存形成持久 SOM 的普遍模式不一致。
Soil organic matter persistence in hyperhumic colluvial soils caused by palaeofires, root inputs and mineral binding
Understanding the formation of long-term persistent soil organic matter (SOM) is key to optimizing soil management and predicting the response of the terrestrial organic carbon (OC) pool to climate change, yet our knowledge of the soil-type dependent weight of different stabilization pathways (e.g., recalcitrance and mineral binding) is fragmentary. Owing to their stratigraphy, the exceptionally SOM-rich (up to 2 m of mineral soil with >5% OC) colluvial slope deposits of Atlantic Europe (Haplic Umbrisol [colluvic/hyperhumic]) are archives of palaeo-environmental conditions including SOM formation pathways. The objective of this study was to determine how the different drivers of persistent SOM formation influenced the formation of these organic-rich soils. For this purpose, we use Holocene (∼9000 yrs) molecular composition records obtained from pyrolysis-GC–MS (Py-GC–MS) and thermally assisted hydrolysis and methylation (THM-GC–MS). The results emphasize three pathways to stability (i.e., persistence on millennial timescales): 1) palaeofires that generated recalcitrant pyrogenic SOM, 2) release of root-derived aliphatic macromolecules (suberin-like SOM), and 3) formation of microbial necromass. Pathways 1 and 2 are controlled by land use: Pathway 1 was relatively important under intense anthropogenic fire regimes and pyrophytic shrubland expansion; Pathway 2 was stimulated during early forest phases and under pasture conditions, when past societies focused vegetation management on grazing instead of fire; Pathway 3 was controlled by binding with aluminium-dominated mineral phases. However, we found indications that Pathway 2 (suberin input and preservation) relied partially on sorptive preservation as well. Aided by structured equation modeling (SEM), we show that the formation of persistent SOM pools was driven by balanced weights of i) microbial vs. plant-derived SOM and ii) intrinsic chemical properties of SOM (recalcitrance continuum) vs. mineral binding/occlusion, which varied in keeping with interactions between past land use, topography and vegetation. These findings are inconsistent with the prevalent paradigm of persistent SOM formation by sorptive/occlusive preservation of microbial necromass alone.
期刊介绍:
Organic Geochemistry serves as the only dedicated medium for the publication of peer-reviewed research on all phases of geochemistry in which organic compounds play a major role. The Editors welcome contributions covering a wide spectrum of subjects in the geosciences broadly based on organic chemistry (including molecular and isotopic geochemistry), and involving geology, biogeochemistry, environmental geochemistry, chemical oceanography and hydrology.
The scope of the journal includes research involving petroleum (including natural gas), coal, organic matter in the aqueous environment and recent sediments, organic-rich rocks and soils and the role of organics in the geochemical cycling of the elements.
Sedimentological, paleontological and organic petrographic studies will also be considered for publication, provided that they are geochemically oriented. Papers cover the full range of research activities in organic geochemistry, and include comprehensive review articles, technical communications, discussion/reply correspondence and short technical notes. Peer-reviews organised through three Chief Editors and a staff of Associate Editors, are conducted by well known, respected scientists from academia, government and industry. The journal also publishes reviews of books, announcements of important conferences and meetings and other matters of direct interest to the organic geochemical community.