The aim of this project is to contribute to the development of recycling fertiliser products based on fish sludge, which can replace parts of the mineral fertiliser currently used in agriculture.
The linearity of nutrient flows in aquaculture, partly originating from land-based feed production, makes current fish farming practices highly unsustainable. Using feed residues and faeces of farmed fish (fish sludge) as a fertiliser product in agriculture, can contribute to closing nutrient cycles. So far, the development of treatment technologies for fish sludge has mainly been motivated by keeping costs low and by reducing odour, rather than by producing high-quality fertiliser products. The coming fertiliser regulation is expected to impose the need for transportable fish sludge products to avoid further soil accumulation of phosphorus in husbandry-dense areas. Therefore, both aquaculture, agriculture and policy makers are in need of more knowledge on how to develop recycling fertiliser products based on fish sludge, which can be transported to areas demanding extra phosphorus fertiliser.
As part of this project, fish sludge from five land-based hatcheries was chemically analysed in 2019 and 2020; four fish sludge products, which were dried by different technologies, a liquid digestate after anaerobic digestion for biogas production and a dried digestate. We conducted two biannual field experiments in the Østfold area in cereals (2019-2020) and an incubation experiment in the laboratory (2020).
The quality of fish sludge as fertiliser varied, also for sludge originating from the same hatchery. The liquid digestate showed good nitrogen effects but drying reduced its nitrogen quality. In dried fish sludge products, nitrogen was mainly present in recalcitrant organic forms, independent of the applied treatment technology. Based on the results we suggest a new hypothesis implying that the nitrogen quality in dried fish sludge will to a larger degree be affected by the ratio of feed residues to excrements than by the applied treatment technology. Accordingly, dried fish sludge with a high content of feed resides will have a better nitrogen effect than fish sludge with a high content of excrements. The solubility of phosphorus was low in all fish sludge products.
The composition of nutrients in fish sludge was unbalanced, with a low ratio between nitrogen and phosphorus and a low potassium content relative to crop demands. Analyses of 2-4 fish sludge samples taken at various treatment points of each of the five treatment plants showed that dewatering reduced the nitrogen and potassium content in the final product. Drying further reduced the nitrogen content of fish sludge. To efficiently utilise nutrients in fish sludge as fertiliser in agriculture, it must be combined, e.g. with mineral fertiliser containing both nitrogen and potassium. In that way fish sludge can be turned into valuable fertiliser products with balanced nutrient ratios.
Most of the fish sludge products were in quality class I or II according to the Norwegian fertiliser regulation, due to elevated cadmium and/or zinc concentrations. According to the current fertiliser regulation, most of the products can hence be used with up to 2 tonn dry matter per hectare and year. This is a considerably larger amount than what is appropriate to be used in practical agriculture based on the phosphorus content in fish sludge. The nitrogen supply on the other is often inadequate as compared to plant demands, unless fish sludge is combined with additional mineral fertiliser. One of the fish sludge products was in quality class III for zinc and can therefore not be utilised as fertiliser in agriculture. Two years after establishment of the field experiments, the cadmium concentration in grains was not significantly affected by fertilisation with fish sludge. The zinc concentration in grains, however, was significantly increased after application of single fish sludge products.
One of the subgoals of the prosjekt has been to investigate whether the nitrogen effect of fish sludge can be predicted by simple laboratory methods. Incubation experiments are a cost-effective method, which has been proven to give a good indication of the plant availability of nitrogen in fish sludge. In the further course of the project, we want to explore whether chemical extractions and spectroscopy can be used for the same aim.
Aim: This project will contribute to the development of recycling fertilisers based on fish sludge that can replace the use of mineral fertiliser in agriculture.
Background: The linearity of nutrient flows makes current fish farming practices in Norway highly unsustainable. Using feed residues and faeces of farmed fish (fish sludge) as fertiliser in agriculture, can contribute to closing nutrient cycles. So far, the development of treatment technologies for fish sludge has mainly been motivated by keeping costs low, and by reducing odour rather than by producing high-quality fertiliser products. The coming fertiliser regulation is expected to impose the need for transportable fish sludge products to avoid soil accumulation of phosphorus in Western Norway. Therefore, both the aquaculture industry, agriculture and policy makers are in need of more knowledge on how to develop recycling fertiliser products based on fish sludge that can replace mineral fertiliser products in agriculture. This project is aiming at filling this gap.
Activities: The project will study the effect of different hatchery types, treatment technologies and feed types on the contents of nutrients and heavy metals in fish sludge. The quality of fish sludge as nitrogen (N) fertiliser and the effect on plant-available phosphorus in the soil will be studied in 2-year field experiments at two sites, and demonstration fields will be established. Also, the mineralisation rates of N in fish sludge products will be studied during an incubation experiment and related to N quality determined by various in-situ laboratory methods, including FTIR analysis (research stay at the University of Copenhagen). The results of the project will be disseminated through popular scientific and scientific publications, presented at conferences and discussed within a reference group. Within the project the post-doc researcher will acquire increased methodological competence, build network and gain project leading skills.