Perez Mercado, Luis Fernando
- Department of Energy and Technology, Swedish University of Agricultural Sciences
- University of San Simón (UMSS)
Research article2024Peer reviewedOpen access
Perez-Mercado, Luis Fernando; Simha, Prithvi; Moreira, Aline Paiva; Paulo, Paula Loureiro; Vinneras, Bjorn
This study evaluated the potential for combining dehydrated human urine with one other form of organic waste to create circular fertilisers tailored to meet the macronutrient demand of 15 major crops cultivated globally. Through a reverse blending modelling approach, data on 359 different organic wastes were used to identify 38 fertiliser blends. Materials found to be particularly suitable as blending materials were various biochars and ashes, due to their low nitrogen and high phosphorus and/or potassium content, and byproduct concentrates, due to their high phosphorus content, since the nitrogen content of human urine is disproportionately higher than its phosphorus content. Several organic wastes were suitable for fertilising more than one crop. The macronutrient content of the simulated fertiliser blends was comparable to that of blended inorganic fertilisers, but only a few blends precisely matched the macronutrient demand of crops. Fertilising crops with some simulated fertilisers would potentially result in excess application of one or more macronutrients, and thus overfertilisation. For organic wastes with data available on their content of six or more heavy metals, it was found that the simulated fertilisers generally met European Union regulations on use of fertilisers of organic origin in agriculture. Overall, these findings suggest that fertiliser blends combining dehydrated human urine and organic wastes, both of which are widely available globally, could replace inorganic blended fertilisers in agriculture. Such recycling would help the global food system and water sector transition to circularity and promote better management of plant-essential nutrients in society.
Reverse blending; Nutrient recycling; Wastewater; Solid organic wastes; Crop yield; Heavy metals
Science of the Total Environment
2024, Volume: 951, article number: 175655Publisher: ELSEVIER
Other Environmental Engineering
Environmental Sciences
DOI: https://doi.org/10.1016/j.scitotenv.2024.175655
https://res.slu.se/id/publ/132235