Long-term organic fertilization decreases soil carbon biodegradability by mediating molecular transformation of dissolved organic matter
Siwei Shi, Danna Chang, Ting Liang, Songjuan Gao, Guopeng Zhou, Weidong Cao
Abstract
Soil dissolved organic matter (DOM), the most biogeochemically active carbon fraction, plays a critical role in regional and global carbon cycling. However, the DOM molecular transformation pathways through which long-term organic fertilization influences soil carbon stability remain poorly understood. Here, we employed carbon quantification, multiple spectroscopic techniques, and ultra-high resolution mass spectrometry to characterize the quantity and quality of soil DOM across depths of 0–20, 20–40, 40–60, 60–80, and 80–100 cm in a 35-year field experiment with chemical fertilizer (CF), cattle manure (CM), and green manure (GM). Compared to CF, CM and GM increased DOM content by 73.0%–162.8% and 81.4%–101.7%, respectively, in the 0–40 cm layers, with CM also enhancing DOM by 24.9%–69.6% in the 40–100 cm layers. DOM in organic-fertilized soils exhibited higher molecular weights and contained 23.0%–26.2% more nitrogen-containing molecular formulas than in CF-treated soils. Organic fertilization also promoted the accumulation of humic-like fluorescence components and recalcitrant compounds such as lignin-, tannin-, and condensed aromatic-like structures. Transformation network analysis showed that organic fertilization increased total number of DOM molecular transformations by 10.4%–14.1%, with positive net transformations observed in tannin- and condensed aromatic-like compounds, suggesting their formation from lignin-like and aliphatic precursors. A 28-day laboratory incubation further suggested that soil DOM under CM or GM exhibited 10.3%–13.2% lower biodegradability than CF treatment. Collectively, these findings demonstrate that long-term organic fertilization drives DOM molecular transformations toward more chemically stable assemblages, thereby reducing its biodegradability and enhancing the potential for soil carbon sequestration.