Abstract
The Aquatic Eddy Covariance (AEC) technique has emerged as an important method to quantify in situ seafloor metabolism over large areas of heterogeneous benthic communities, enabling cross-habitat comparisons of seafloor productivity. However, the lack of a corresponding sampling protocol to perform biodiversity comparisons across habitats is impeding a full assessment of marine ecosystem metabolism. Here, we study a range of coastal benthic habitats, from rocky-bed communities defined by either perennial macroalgae or blue mussel beds to soft-sediment communities comprised of either seagrass, patches of different macrophyte species or bare sand. We estimated that the maximum contribution to the AEC metabolic flux can be found for a seafloor area of approximately 80 m2 with a 5 meter upstream distance of the instrument across all the habitats. We conducted a sampling approach to characterize and quantify the dominant features of biodiversity (i.e., community biomass) within the main seafloor area of maximum metabolic contribution (i.e., gross primary production and community respiration) measured by the AEC. We documented a high biomass contribution of the macroalgal Fucus vesiculosus, the seagrass Zostera marina and the macroinvertebrate Mytilus edulis to the net ecosystem metabolism of the habitats. We also documented a significant role of the bare sediments for primary productivity compared to vegetated canopies of the soft sediments. The AEC also provided insight into dynamic short-term drivers of productivity such as PAR availability and water flow velocity for the productivity estimate. We regard this study as an important step forward, setting a framework for upcoming research focusing on linking biodiversity metrics and AEC flux measurements across habitats.
Highlights
Coastal benthic zones are diverse and productive environments capable of sustaining vital ecosystem functions and providing valuable societal services [1]
The FV site showed the largest O2 production (NEM was almost twice as high as Bare sand (BS), i.e., 11.2±6.3 mmol O2 m-2 d-1), whereas the Blue mussel reef (BM) site showed the largest net O2 uptake compared to the other habitats (NEM was 17 times more negative than in the SG site, -42.1±3.4 mmol O2 m-2 d-1) (Table 1, Fig 5A)
This is the first time that benthic biodiversity surveys across habitats have been performed exclusively upon the multidirectional Aquatic Eddy Covariance (AEC) flux footprint characteristics
Summary
Coastal benthic zones are diverse and productive environments capable of sustaining vital ecosystem functions and providing valuable societal services [1]. The contribution of different elements of the benthic biodiversity such as richness of species, abundance, biomass or range of habitats to the ecosystem metabolism is key for the functioning of coastal ecosystems e.g., [2,3,6,7]. Microphytobenthos, a key coastal primary producer, has a crucial role for the overall ecosystem metabolism of unvegetated marine habitats e.g., [10,11]. Coastal ecosystems harbour a high diversity of macrobenthic consumers that contribute to the ecosystem metabolism reflected by elevated benthic O2 uptake e.g., [3, 6,12]. The majority of the studies on benthic biodiversity and/or ecosystem metabolism have been conducted within the same type of habitat e.g., [8,9,10,11,12,13], and cross-site information from different habitats with complex emergent structures (e.g., seagrass, seaweeds, and blue mussels) is largely lacking
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