As conventional fisheries face growing challenges from stock depletion, low-trophic fisheries are emerging as a promising pathway for sustainable harvesting. In this context, the numerous and widespread marine copepod Calanus finmarchicus offers an easily accessible lower-trophic-level resource that can be responsibly harvested in the North Atlantic Ocean.

In Norway, Calanus fisheries are already established, contributing to the production of natural health oils rich in marine nutrients, as well as high-quality animal feed and sustainable ingredients for aquaculture. These tiny crustaceans, a key component of the marine food web, represent an opportunity for low-impact harvesting. However, as fishing pressure on C. finmarchicus stocks grows, so does the urgency to sustainably manage this blue resource.

To address this challenge, the second field campaign of the CliN-BluFeed project was launched on 4 of June 2025 (Figure 1), aiming to improve the understanding and monitoring of C. finmarchicus distributions and dynamics. This second field campaign deployed two autonomous underwater vehicle (AUV) gliders and one unmanned surface vehicle (USV) Sailbuoy (Figure 2), equipped with acoustic and optical sensors, to collect a unique dataset of in situ observations of C. finmarchicus in the Norwegian Sea.

The CliN-BluFeed project is funded by Sustainable Blue Economy Partnership (SBEP), an Horizon Europe co-funded partnership, and brings together the Akvaplan-niva, AIR Centre, Cyprus Subsea Consulting and Services, the Institute of Oceanology of the Polish Academy of Sciences (IO PAN) and the Alfred Wegener Institute (AWI). Its main objective is to develop methodologies that advance the Norwegian Sea Calanus fishery as a sustainable resource using autonomous marine monitoring technologies coupled with remote sensing, artificial intelligence, simulation modelling, and experimental investigations.

During this second field campaign, the AIR Centre developed the Multi-Satellite Ocean Colour Visualiser (Figure 3), a tool that integrates the Sailbuoy’s real-time position with satellite products such as RGB composites, chlorophyll-a concentration, and red reflectance from different missions (Sentinel-3, MODIS AQUA and VIIRS). This visualiser enables near-real-time (NRT) visualisation and helps guide the autonomous underwater (AUV) and surface vehicles (USV) towards oceanographic features of interest. It also provides large-scale insights into the physical and biological ocean conditions relevant to detecting Calanus swarms.

In the coming days and weeks, we eagerly anticipate acquiring various cloud-free satellite images that will enable coincident observations from both satellites and the in situ gliders and Sailbuoy. This will support the development of satellite-based models to improve the detection and monitoring of Calanus swarms that enhance our understanding of the spatial and temporal dynamics of Calanus in the Norwegian Sea and ultimately promote the sustainable harvesting of this vital blue food resource.