Periphyton has the potential to increase phosphorus use efficiency in paddy fields

The phosphorus (P) supply is mismatched with rice demand in the early and late stages of rice growth, which primarily results in low P use efficiency and high environmental risk. In recent years, the use of the natural periphyton in nutrient regulation in paddy fields has attracted much research int...

Full description

Saved in:
Bibliographic Details
Published in:The Science of the total environment 2020-06, Vol.720, p.137711-137711, Article 137711
Main Authors: Li, Jiu-yu, Deng, Kai-ying, Cai, Shu-jie, Lu, Hai-long, Xu, Ren-kou
Format: Article
Language:English
Subjects:
Bioavailability
Decomposition
Migration
Periphyton
Phosphorus
Proliferation
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The phosphorus (P) supply is mismatched with rice demand in the early and late stages of rice growth, which primarily results in low P use efficiency and high environmental risk. In recent years, the use of the natural periphyton in nutrient regulation in paddy fields has attracted much research interest. However, a mechanistic understanding of the action of periphyton on P biogeochemical cycling during the pivotal stages of rice growth has received little attention. In this study, the influence of periphyton proliferation on the soil surface and its consequential decomposition on P migration and bioavailability were investigated in two paddy soils using two microcosm experiments. The results showed that periphyton rapidly accumulated fertilizer P when it proliferated on the soil surface under favorable light condition, which led to more fertilizer P being stored on the soil surface and less P being fixed by soil particles or transported via runoff into the water bodies. The decomposition of periphyton under unfavorable light condition not only increased soil soluble reactive P, but also increased the amount of easily available P species, such as labile P, AlP, FeP, and mobilized OP. Thus, periphyton colonizing the soil surface in the early stage of rice growth could act as a P sink and decrease the P environmental risk, and its decomposition in the late stage of rice growth could act as a P source and activator. Phosphorus bioavailability regulated by periphyton could be synchronous with rice needs. Thus, periphyton has the potential to increase P use efficiency in paddy fields. [Display omitted] •Periphyton could rapidly accumulated fertilizer P in the early stage of rice growth.•Decomposition of periphyton increased P bioavailability in the late stage of rice growth.•Periphyton could act as a buffer and activator for P bioavailability to match rice demand.•Biofertilizer based on periphyton would have the potential to increase P use efficiency.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2020.137711