Abstract
Purpose The global capacity of ofshore wind energy is rapidly expanding, with the North Sea leading this growth. However, this region also hosts some of the world’s oldest ofshore wind farms, requiring decommissioning in the coming years. Apart from their benefts for energy generation, constructing and decommissioning ofshore wind farms physically afect the marine ecosystem. This study aims to develop characterization factors to quantify impacts on marine benthic biodiversity, assessing changes in species richness and accounting for both positive and negative efects.
Method The study utilizes data on species richness at 17 artifcial ofshore structures and reference seabed sites in the North Sea. Polynomial models are developed to express the species richness on the structure as a function of structure age. The study considers two construction scenarios and three decommissioning scenarios and compares species richness on the artifcial structure to the reference seabed. Additionally, it investigates species composition changes in diferent taxonomic groups and alien species. The richness models are used to develop characterization factors for biodiversity impacts, expressed as the time-integrated potentially disappeared fraction of species.
Results and discussion The developed characterization factors quantify potential loss or gain of species across taxonomic groups, enhancing the representation of biodiversity in life cycle assessment. While species richness on ofshore structures generally increases over time, the net biodiversity impacts depend on the seabed type on which the structure is constructed. The characterization factors indicate that for sandy seabed, species richness on the structure exceeds that of the reference seabed after ~13 years. However, over a 25-year lifetime, construction on sandy seabed generally results in a net species loss due to declining species richness after the peak at a 13-year lifetime. Construction on hard seabed supports a net gain of species. Furthermore, characterization factors indicate that partial decommissioning will preserve 80–99% of the species richness on turbine structures. The net efect on ecosystem functioning is yet unclear, depending on, e.g., recolonization opportunities, reference state, and interaction with other marine activities. Conclusion The developed characterization factors quantify both positive and negative biodiversity impacts from habitat changes associated with ofshore wind farm construction and decommissioning in the North Sea, thus providing a basis for understanding and managing the ecological consequences of ofshore wind farm projects. The fndings indicate that the construction and decommissioning activities will cause changes in the total species richness and the richness of alien species and shifts in richness between taxonomic groups.