Abstract
Understanding ecosystem dynamics within shallow shelf seas is of great importance to support marine spatial management of natural populations and activities such as fishing and offshore renewable energy production to combat climate change. Given the possibility of future changes, a baseline is needed to predict ecosystems responses to such changes. This study uses Bayesian techniques to find the data-driven estimates of interactions among a set of physical and biological variables and a human pressure within the last 30 years in a well-studied shallow sea (North Sea, UK) with four contrasting regions and their associated ecosystems. A hidden variable is incorporated to model functional ecosystem change, where the underlying interactions dramatically change, following natural or anthropogenic disturbance. Data-driven estimates of interactions were identified, highlighting physical (e.g. bottom temperature, potential energy anomaly) and biological variables (e.g. sandeel larvae, net primary production) to be strong indicators of ecosystem change. There was consistency in the physical and biological variables, identified as good indicators in three of the regions, however the shallower region (with depths < 50 m, that is targeted for static offshore wind developments) was the most dissimilar. The use of contrasting regions provided useful insights on responses linked to ecosystem disturbances and identified the top predators as better indicators for each region, with the harbour porpoise being a particularly valuable indicator of ecosystem change across most regions. Another important finding was the dramatic changes in the strength of many interactions over time. This suggests that physical and biological indicators should only be used with additional temporal information, as changes in strength led to the identification of two potentially significant periods of ecosystem change (after 2005 and after 2010), linked to physical pressures (e.g. cold-water anomalies, seen in bottom temperatures; salinity changes, seen in the potential energy anomaly) and primary production changes. The hidden variable also modelled a change in the early 2000s for all the regions and identified maximum chlorophyll-a and sea surface temperature as some of the better indicators of these ecosystem changes.
Highlights
There is about to be an abrupt step-change in the use of our shallow shelf seas around the globe, by the addition of large-scale offshore renewable energy developments to combat climate change
We present identified dependency data-driven estimates of in teractions that are currently shaping the ecosystem dynamics in space across UK waters and how they are changing with time, identifying the best indicators leading to such changes
Many more relationships were identified with BT, as compared to SST, in all regions, except for the shallow central North Sea
Summary
There is about to be an abrupt step-change in the use of our shallow shelf seas around the globe, by the addition of large-scale offshore renewable energy developments to combat climate change. The extent of these developments may end up using > 30% of shallow shelf seas (Scottish Sectoral Marine Plan for Offshore Wind Energy, 2020; Outer Continental Shelf Renewable Energy Leases, BOEM USA, 2021; Available at 14th FYP Development Plan for Renewable Energy, 2020; the 14th FYP Development Plan for Renewable Energy, China, 2020). We need to make the best use of knowledge about interactions and mechanisms from shallow shelf sea ecosystems to provide an effective baseline to predict their responses to natural versus anthropogenic changes, providing rapid strategic advice for more sustainable future spatial use of our seas
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