Abstract
The Clarion-Clipperton Zone (CCZ) is a 4 million km2 area in the eastern Central Pacific Ocean exhibiting large variability in environmental parameters, particularly oxygen and primary production, that is being targeted for deep-sea polymetallic nodule mining. This remote region’s pelagic biology is very poorly sampled, including for micronekton and zooplankton that provide essential ecosystem services such as carbon flux and support for commercial fisheries. We built a baseline of deep scattering layer (DSL) depths and vertical migration behaviors, proxies for mesopelagic micronekton and zooplankton communities, using shipboard acoustic Doppler current profiler datasets. Acoustic data (38 kHz, 75 kHz) were compiled from research cruises passing near or through the CCZ (2004–2019), and environmental data (mean midwater oxygen partial pressure, surface chlorophyll-a, and sea surface height anomaly) were assembled from the World Ocean Atlas and satellite oceanographic datasets. Our results suggest that midwater oxygen, associated with the Eastern Tropical Pacific Oxygen Minimum Zone (OMZ), is the strongest predictor of daytime DSL depths and the proportions of midwater populations that undergo vertical migration in this region. We used these relationships to predict micronekton and zooplankton behaviors across the CCZ, including licensed mining exploration areas and no-mining reserves. While the OMZ encompasses most licensed exploration areas, the current network of reserves lies outside of the core OMZ and ultimately may not represent or protect the pelagic OMZ fauna at highest risk from mining impacts. This research will further assist in developing resource exploitation regulations by the International Seabed Authority, and will provide mesopelagic baseline information for monitoring changes that may occur in the CCZ once industrial-scale mining begins.
Highlights
The deep pelagic ocean likely contains a greater abundance and higher biomass of organisms than any other major ecosystem
While we mainly focused on strong mesopelagic deep scattering layer (DSL), it is worth noting that weaker migratory and non-migratory DSLs extended below 1,000 m in our 38 kHz datasets (Supplementary Figure 1)
Our analyses of acoustically measured micronekton and large zooplankton migratory behaviors highlight the significance of the Eastern Tropical Pacific Oxygen Minimum Zone (OMZ) in structuring mesopelagic communities across the Clarion-Clipperton Zone (CCZ)
Summary
The deep pelagic ocean likely contains a greater abundance and higher biomass of organisms than any other major ecosystem. This ecosystem is largely under-represented in global databases of marine biological records, and deep pelagic communities remain the least-known faunal group on Earth (Webb et al, 2010). While swimbladdered fishes and gas-bearing siphonophores can dominate these acoustic signals, DSLs vary globally across pelagic ecosystems in their faunal composition, as well as daytime depths and vertical movements (Klevjer et al, 2016; Sutton et al, 2017). Information about the proportions of mesopelagic fauna carrying out DVM on local and regional scales is minimal, and this is a key attribute affecting active carbon flux and the coupling strength between the epi- and mesopelagic
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