Long-term green manuring increases soil carbon sequestration via decreasing qCO2 caused by lower microbial phosphorus limitation in a dry land field

Organic fertilization in agroecosystems is an efficient fertilization management for sequestering carbon (C). Microbial metabolism affects C sequestration by influencing the rate of soil C mineralization, however, the responses of microbial metabolism limitation and soil respiration to different org...

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Published in:Agriculture, ecosystems & environment ecosystems & environment, 2024-10, Vol.374, p.109142, Article 109142
Main Authors: Ma, Zhengbo, Liang, Ting, Fu, Haoran, Ma, Qingxu, Chang, Danna, Zhang, Jiudong, Che, Zongxian, Zhou, Guopeng, Cao, Weidong
Format: Article
Language:English
Subjects:
agriculture
agroecosystems
arid lands
carbon
carbon sequestration
cattle manure
China
Ecoenzymatic stoichiometry
environment
enzymes
Fertilization management
green manures
least squares
metabolism
microbial activity
Microbial carbon use efficiency
Microbial nutrient limitation
mineralization
nitrogen
nitrogen fertilizers
phosphorus
soil
Soil respiration
stoichiometry
wheat straw
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Summary:Organic fertilization in agroecosystems is an efficient fertilization management for sequestering carbon (C). Microbial metabolism affects C sequestration by influencing the rate of soil C mineralization, however, the responses of microbial metabolism limitation and soil respiration to different organic fertilizations remain unclear. Here, an experiment started from 1988 in a dry land of Northwest China was used to explore the mechanisms of C sequestration under five typical fertilization managements, namely no fertilization (CK), mineral nitrogen fertilizer (NF), wheat straw (WS), cattle manure (CM), and green manure (GM). The results indicated that the WS, CM, and GM treatments increased C sequestration rates by 28.3 %, 119.4 %, and 72.1 % in the 0–60 cm layer, compared with NF, whereas C sequestration efficiency was the greatest in the GM treatment. In addition, organic fertilization treatments increased the contents of soil nutrients across all the soil layers to varying degrees, and the activities of C, nitrogen (N), and phosphorus (P) -related enzyme in 0–60 cm soil layer also increased by 219.1∼236.9 %, 236.7∼774.5 %, and 2.5∼36.5 % compared with NF. Enzymatic stoichiometry indicated that the soil microbial metabolism across all soil layer was mainly limited by P. Organic fertilization alleviated the microbial P limitation and decreased the microbial metabolic quotient (qCO2) in 0–20 cm soil layer. And GM treatment showed the lowest P limitation and qCO2 in all soil layers. The partial least square path model demonstrated that microbial P limitation was the main driver affecting qCO2. Alleviating the microbial P limitation decreased unnecessary C loss during microbial catabolism, converting more C to MBC, thereby increasing CUE and lowering qCO2. In summary, green manuring is the most efficient practice to benefit C sequestration across all fertilization managements in this study. [Display omitted] •Long-term fertilization management resulted in microbial P limitation across all soil layers.•Green manuring exhibited the lowest microbial P limitation in all soil layers.•Green manuring got the greatest carbon sequestration efficiency across all organic fertilization management.•P limitation was the main driver affecting qCO2 and microbial C use efficiency.
ISSN:0167-8809
1873-2305
DOI:10.1016/j.agee.2024.109142