Abstract
Phosphorus (P) is critical for food production. However, it has been managed unsustainably for decades and geopolitical challenges complicate its availability. While accessible P-rock deposits are linearly exploited, excessive fertilization practices lead to P loss from land to water, and thus, eutrophication. The release of legacy P from sediments to the water column, i.e. internal P loading, sustains global eutrophication issues. Sediment removal and its subsequent reuse as soil amendment can simultaneously lower internal P loadings and create a new P resource. However, the plant bioavailability of sedimentary P, especially Fe-P, is rather controversial. In this study, the direct P fertilizer effect of fresh lake sediment, lake sediment after Fe-P removal, amorphous Fe-P, and the reduced Fe-P mineral vivianite on barley was investigated and compared to the conventional mineral P fertilizer triple superphosphate (TSP). Fresh sediment, amorphous Fe-P, and vivianite fertilization significantly increased biomass and P uptake compared to the 0-control, while the Fe-P removal from the sediment reduced both effects. The P use efficiency was generally lower than for TSP and decreased in the order amorphous Fe-P > fresh sediment > vivianite > sediment after Fe-P removal. In a parallel soil incubation without barley growth P diffusion from the tested alternative substrates was not observed. We conclude that fresh lake sediment has P fertilizer potential with amorphous Fe-P as a significant contributor. Further, fertilization with fresh sediment and Fe-P can increase soil adsorptive capacities potentially reducing leaching but also creating dependency of plant P bioavailability on plant-soil interactive mechanisms.
| Originalsprog | Engelsk |
|---|---|
| Artikelnummer | 2362503 |
| Tidsskrift | Sustainable Environment |
| Vol/bind | 10 |
| Udgave nummer | 1 |
| Antal sider | 15 |
| ISSN | 2765-8511 |
| DOI | |
| Status | Udgivet - 2024 |
Bibliografisk note
Funding Information:This study was jointly funded by the Poul Due Jensen Fond (Grundfos Foundation) [2020-068]. The authors would like to thank Carina Kronborg Lohmann, Rikke Orloff Holm, Birthe Christensen, and Janus Tem Jensen, the superb technicians of the Ecology lab at the University of Southern Denmark, for their technical support and sample measurements. Further, we would like to thank Thomas Prot and Leon Korving from the Wetsus European Center of Excellence for Sustainable Water Technology for the provision of the vivianite material and their comments on the first manuscript version.
Funding Information:
This work was supported by the Poul Due Jensen Fond/Grundfos Foundation under Grant [2020-068]. This study was jointly funded by the Poul Due Jensen Fond (Grundfos Foundation) [2020-068]. The authors would like to thank Carina Kronborg Lohmann, Rikke Orloff Holm, Birthe Christensen, and Janus Tem Jensen, the superb technicians of the Ecology lab at the University of Southern Denmark, for their technical support and sample measurements. Further, we would like to thank Thomas Prot and Leon Korving from the Wetsus European Center of Excellence for Sustainable Water Technology for the provision of the vivianite material and their comments on the first manuscript version.
Publisher Copyright:
© 2024 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group.