Soil pH and Nutrient Stoichiometry as Key Drivers of Phosphorus Availability in Crop Rotation Systems

Soil pH and Nutrient Stoichiometry as Key Drivers of Phosphorus Availability in Crop Rotation Systems

Crop rotation systems profoundly influence soil phosphorus (P) dynamics through physicochemical and microbial interactions. The mechanisms regulating P availability under various rotational practices remain poorly understood. This five-year field experiment investigated the effects of four rotation...

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Bibliographic Details
Main Authors: Yi Yuan, Yi Zhu, Yichen Zhao, Meng Wang, Zhaoming Qu, Dongqing Lv, Yanli Liu, Yan Song, Tingting Wang, Chengliang Li, Haojie Feng
Format: Article
Language:English
Published: MDPI AG 2025-04-01
Series:Agronomy
Subjects:
crop rotation
phosphorus fractions
soil pH
acid phosphatase activity
alkaline phosphatase activity
C/N
Online Access:https://www.mdpi.com/2073-4395/15/5/1023
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Summary:Crop rotation systems profoundly influence soil phosphorus (P) dynamics through physicochemical and microbial interactions. The mechanisms regulating P availability under various rotational practices remain poorly understood. This five-year field experiment investigated the effects of four rotation systems (WM: wheat–maize; WP: wheat–peanut; WS: wheat–soybean; MV: maize–hairy vetch) on soil P fractions, phosphatase activities, P-cycling gene abundance, and their interactions with soil properties. The WM rotation substantially reduced soil pH (6.29) while increasing labile P fractions (Ca<sub>2</sub>-P) and moderately labile P (Al-P, Fe-P, and Ca<sub>8</sub>-P), which was attributed to enhanced acid phosphatase activity. The WP rotation elevated soil pH (8.13) but reduced P availability due to calcium–P immobilization. The MV rotation stimulated microbial P cycling, exhibiting the highest <i>phoD</i> (2.01 × 10<sup>6</sup> copies g<sup>−1</sup>) and <i>phnK</i> (33,140 copies g<sup>−1</sup>) gene abundance, which was linked to green manure-induced microbial activation. Redundancy analysis identified soil pH, total nitrogen, and stoichiometric ratios (C/N and N/P) as key shared drivers of P fractions and enzymatic activity. Partial least squares path modeling (PLS–PM) indicated that crop rotation directly regulated P availability through pH modulation (r = −0.559 ***) and the C/N ratio (r = 0.343 ***) while indirectly regulating P fractions through phosphatase activity. Lower C/N ratios (<10) across all rotation regimes amplified the carbon limitation in the process of P transformation, indicating that exogenous carbon inputs and appropriate stoichiometry in the soil should be optimized. The results of this study inform the selection of suitable crop rotation patterns for sustainable agriculture.
ISSN:2073-4395

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