Lithological Controls on Soil Aggregates and Minerals Regulate Microbial Carbon Use Efficiency and Necromass Stability.

IF 10.8 1区 环境科学与生态学 Q1 ENGINEERING, ENVIRONMENTAL 环境科学与技术 Pub Date : 2024-11-14 DOI:10.1021/acs.est.4c07264
Peilei Hu, Wei Zhang, Andrew T Nottingham, Dan Xiao, Yakov Kuzyakov, Lin Xu, Hongsong Chen, Jun Xiao, Pengpeng Duan, Tiangang Tang, Jie Zhao, Kelin Wang
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Abstract

Microbial carbon (C) use efficiency (CUE) drives soil C formation, while physical-chemical protection stabilizes subsequent microbial necromass, both shaped by soil aggregates and minerals. Soils inherit many properties from the parent material, yet the influence of lithology and associated soil geochemistry on microbial CUE and necromass stabilization remains unknow. Here, we quantified microbial CUE in well-aggregated bulk soils and crushed aggregates, as well as microbial necromass in bulk soils and the mineral-associated organic matter fraction, originating from carbonate-containing (karst) and carbonate-free (clastic rock, nonkarst) parent materials along a broad climatic gradient. We found that aggregate crushing significantly increased microbial CUE in both karst and nonkarst soils. Additionally, compared to nonkarst soils, calcium-rich karst soils increased macroaggregate stability and decreased the ratio of oligotrophic to copiotrophic microbial taxa, leading to a reduction in microbial CUE. Moreover, microbial CUE was negatively associated with iron (hydr)oxides in karst soils, attributed to the greater abundance of iron (hydr)oxides and higher soil pH. Despite the negative effects of soil aggregation and minerals on microbial CUE, particularly in karst soils, these soils concurrently showed greater microbial necromass stability through organo-mineral associations compared to nonkarst soils. Consequently, (i) bedrock lithology mediates the effects of aggregates and minerals on microbial CUE and necromass stability; and (ii) balancing minerals' dual roles in diminishing microbial CUE and enhancing microbial necromass stability is vital for optimizing soil C preservation.

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对土壤团聚体和矿物质的岩性控制可调节微生物的碳利用效率和新陈代谢的稳定性。
微生物碳(C)利用效率(CUE)推动了土壤碳的形成,而物理化学保护则稳定了随后的微生物新陈代谢,两者都是由土壤团聚体和矿物质形成的。土壤继承了母质的许多特性,但岩性和相关的土壤地球化学对微生物CUE和微生物尸体稳定的影响仍未可知。在这里,我们对来自含碳酸盐(岩溶)和不含碳酸盐(碎屑岩、非岩溶)母质的、沿广泛气候梯度分布的、集聚良好的块状土壤和破碎集料中的微生物CUE,以及块状土壤和与矿物相关的有机物部分中的微生物新生物量进行了量化。我们发现,在岩溶土壤和非岩溶土壤中,集料破碎会显著增加微生物的CUE。此外,与非喀斯特土壤相比,富含钙质的喀斯特土壤增加了大集料的稳定性,降低了寡养微生物类群与共养微生物类群的比例,导致微生物CUE降低。此外,岩溶土壤中的微生物CUE与铁(水)氧化物呈负相关,这是因为铁(水)氧化物更丰富,土壤pH值更高。尽管土壤团聚和矿物质对微生物 CUE 有负面影响,尤其是在岩溶土壤中,但与非岩溶土壤相比,这些土壤同时通过有机矿物质关联显示出更高的微生物坏死物质稳定性。因此,(i) 基岩岩性介导了团聚体和矿物质对微生物CUE和微生物尸体稳定性的影响;(ii) 平衡矿物质在降低微生物CUE和提高微生物尸体稳定性方面的双重作用对优化土壤C保存至关重要。
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来源期刊
环境科学与技术
环境科学与技术 环境科学-工程:环境
CiteScore
17.50
自引率
9.60%
发文量
12359
审稿时长
2.8 months
期刊介绍: Environmental Science & Technology (ES&T) is a co-sponsored academic and technical magazine by the Hubei Provincial Environmental Protection Bureau and the Hubei Provincial Academy of Environmental Sciences. Environmental Science & Technology (ES&T) holds the status of Chinese core journals, scientific papers source journals of China, Chinese Science Citation Database source journals, and Chinese Academic Journal Comprehensive Evaluation Database source journals. This publication focuses on the academic field of environmental protection, featuring articles related to environmental protection and technical advancements.
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