Global Phosphorus Enrichment Reshapes Terrestrial Phosphorus Cycling.
- 2026-04
- Global change biology 32(4)
- Zixin Chen
- Kai Dong
- Julian Helfenstein
- Dafeng Hui
- Constantin M Zohner
- Frank Hagedorn
- Manuel Delgado-Baquerizo
- Adam R Martin
- Jiguang Feng
- Nan Yang
- Xinli Chen
- Laurent Augusto
- Qi Deng
- Enqing Hou
- Mingkai Jiang
- Qingshui Yu
- Haihua Shen
- Jordi Sardans
- Josep Peñuelas
- Hans Lambers
- Jingyun Fang
- Zhengbing Yan
- PubMed: 41923270
- DOI: 10.1111/gcb.70827
Study Design
- Type
- Meta-Analysis
- Methods
- global meta-analysis of 1315 observations from 176 studies across diverse natural terrestrial ecosystems
Anthropogenic phosphorus (P) inputs are rapidly altering terrestrial P cycling through plant - soil - microbial interactions; however, global patterns and underlying mechanisms driving these changes remain poorly understood. By performing a global meta-analysis of 1315 observations from 176 studies across diverse natural terrestrial ecosystems, we found that P addition increased P concentrations in foliage, stems, roots, and litter by 62%, 114%, 100% and 63%, respectively. Soil total P, plant-available P, and microbial P concentrations rose by 43%, 221%, and 70%, while leaf P-resorption efficiency and soil phosphatase activity declined by 23% and 15%, respectively. Stem P and soil phosphatase activity exhibited consistent trends across tropical, temperate, and boreal zones, suggesting climate-specific P acquisition strategies. In addition, foliar P responses diverged among ecosystem and plant functional types. These responses were primarily regulated by background soil total P concentration, precipitation, soil pH, and P addition duration and rate. Our findings provide critical insights into the potential consequences of increasing anthropogenic P inputs in natural terrestrial ecosystems, improving our understanding of nutrient cycling and informing future ecosystem management under ongoing global change.